Iron deficiency and iron deficiency anemia among preschool aged Inuit children living in Nunavut
Angela Pacey
School of Dietetics and Human Nutrition, McGill University, Montréal
October 2009
A thesis submitted to McGill University in partial fulfilment of the requirements of the degree of Master of Science
© Angela Pacey 2009
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ABSTRACT
Limited information is available about iron deficiency and iron deficiency anemia (IDA)
among preschool-aged Inuit children. A cross-sectional survey was conducted with 388
Inuit children, aged 3 to 5 years, from 16 Nunavut communities. Interviews were
conducted on dietary and household characteristics. Height, weight and biomarkers of
iron status and Helicobacter pylori (H. pylori) exposure were measured. The prevalence
of iron deficiency and IDA was calculated and risk factors were examined. The
prevalence of iron deficiency was 19.2%, of IDA was 4.5% and of anemia was 20.3%.
Only 0.3% of children had usual iron intakes below the Estimated Average Requirement.
H. pylori exposure, food insecurity and household crowding were not associated with
iron deficiency or IDA. Three to four year olds were more likely to be iron deficient than
5 year olds. Boys were more likely to be iron deficient than girls.
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RÉSUMÉ
Peu d’informations sont disponibles sur la carence en fer et l’anémie due à une carence
en fer (ACF) chez les Inuits d’âge pré-scolaire. Un sondage transversales a été conduit
avec 388 enfants Inuit âgés de 3 à 5 ans, dans 16 communautés du Nunavut. Des
interviewers ont conduit des entrevues alimentaires et des questionnaires à propos des
caractéristiques des ménages. La taille, le poids, ainsi que des marqueurs biologiques du
niveau de fer et de l’exposition à Helicobacter pylori ont été mesurés. La prévalence de la
carence en fer et de l’ACF a été calculée et les facteurs de risque ont été examinées. La
prévalence de la carence en fer a été 19.2%, de l’ACF a été 4.5% et de l’anémie a été
20.3%. Seulement 0.3% des enfants avaient des apports habituels en fer sous le besoin
moyen estimatif. L’exposition à H. pylori, l’insécurité alimentaire et le nombre
d’habitants par ménage n’étaient pas associés à une carence en fer ou à de l’ACF. La
carence en fer était plus élevée chez les enfants âgés de 3 à 4 ans que chez ceux de 5 ans.
La carence en fer était aussi plus élevée chez les garçons que chez les filles.
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STATEMENT OF SUPPORT
Funding for this study was provided through Government of Canada International Polar
Year, Government of Nunavut Department of Health and Social Services, Canadian
Institutes for Health Research. Ms. Pacey was financially supported by a stipend provided
by Dr. Grace Egeland and through a grant from the Nasivvik grant.
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ACKNOWLEDGEMENTS
I am very grateful to my supervisor, Dr. Grace Egeland, for exposing me to so many
fascinating experiences, for her on-going input, support and patience. I feel lucky to have
had such insightful committee members, Dr. Hope Weiler and Dr. Katherine Gray-
Donald, who offered encouragement and their expertise throughout. Special thanks to Dr.
Nelofar Sheikh for her dedication to data management and to Louise Johnson-Down who
coordinated the dietary data entry and performed the nutrient intake analyses. Special
thanks also to Donna Leggee, Sherry Agellon and Jennifer Jamieson for their assistance
and teachings in laboratory analyses of iron status. My Master’s of Nutrition training was
truly a collective effort by all of the above-mentioned mentors.
We would like to acknowledge the work of the 2007 and 2008 research teams
including Nancy Faraj, Christine Ekidlak, Laureen Pameolik, Kathy Morgan, Lauren
Goodman and Jessy El Hayak. We whole-heartedly appreciate the assistance provided to
us by the communities, hamlet offices, the schools, the health centre staff and our
steering committee. Finally, thank you to the participating children and their families.
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CONTRIBUTION OF AUTHORS
Ms. Pacey assisted considerably in data collection, research team training, data entry,
laboratory analyses and thesis and manuscript writing. Dr. Grace Egeland planned and
guided the research methods and statistical analyses and reviewed and gave feedback on
this thesis and manuscript.
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TABLE OF CONTENTS ABSTRACT...................................................................................................................... II
RÉSUMÉ ........................................................................................................................ III STATEMENT OF SUPPORT .............................................................................................. IV
ACKNOWLEDGEMENTS ...................................................................................................V CONTRIBUTION OF AUTHORS ........................................................................................ VI
LIST OF TABLES ............................................................................................................ IX LIST OF FIGURES .............................................................................................................X
LIST OF APPENDICES ..................................................................................................... XI LIST OF ABBREVIATIONS ............................................................................................. XII
1 STUDY BACKGROUND ................................................................................................1 1.1. ABORIGINAL PEOPLES AND INUIT IN CANADA......................................................................................1 1.2. HEALTH CARE DELIVERY IN NUNAVUT .................................................................................................2 1.3. INUIT CHILD HEALTH SURVEY ..............................................................................................................2
2 LITERATURE REVIEW................................................................................................3 2.1. IRON METABOLISM, REQUIREMENTS AND DEFICIENCY.........................................................................3
2.1.1. Iron metabolism 3 2.1.2. Iron requirements and measuring dietary intake 5 2.1.3. Health outcomes of iron deficiency 9
2.2. POPULATION-BASED RESEARCH IN IRON DEFICIENCY.........................................................................11 2.2.1. Measuring iron status 11 2.2.2. Iron deficiency among Inuit children: review of prevalence estimates 14
2.3. ETIOLOGY OF IRON DEFICIENCY AND ANEMIA AMONG CHILDREN .....................................................17 2.3.1. Overview of causes of iron deficiency and IDA in children 17 2.3.2. Dietary factors related to iron deficiency 17 2.3.3. Helicobacter pylori 20 2.3.4. Underlying risk factors for iron deficiency 30
3 RATIONALE .............................................................................................................38 3.1. OBJECTIVES ..........................................................................................................................................39 3.2. HYPOTHESES.........................................................................................................................................39
4 METHODS................................................................................................................40 4.1. PARTICIPATORY RESEARCH PROCESS ..................................................................................................40 4.2. SAMPLE SIZE CALCULATION.................................................................................................................40 4.3. STAFFING AND TIMEFRAME FOR DATA COLLECTION...........................................................................41 4.4. RECRUITMENT ......................................................................................................................................42 4.5. ETHICS APPROVAL ................................................................................................................................43 4.6. INTERVIEWS ..........................................................................................................................................43
4.6.1. Interview training 43 4.6.2. Inuktitut translations 44 4.6.3. Written informed consent 45 4.6.4. Study numbers and confidentiality 45 4.6.5. Participant compensation 45 4.6.6. Demographic information and household characteristics 46 4.6.7. 24-hour dietary recall 46 4.6.8. Food frequency questionnaire 46 4.6.9. Quality control for interview component 47
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4.7. CLINICAL DATA COLLECTION...............................................................................................................47 4.7.1. Anthropometry 48 4.7.2. Blood sample collection 48 4.7.3. HemoCue™ 49
4.8. PLASMA SAMPLE PREPARATION...........................................................................................................50 4.9. LABORATORY ANALYSES .....................................................................................................................51
4.9.1. Measurement of C-reactive protein 51 4.9.2. Measurement of Helicobacter pylori exposure status 52 4.9.3. Measurement of ferritin 53
4.10. DATA MANAGEMENT..........................................................................................................................54 4.11. STATISTICAL ANALYSES.....................................................................................................................56
5 MANUSCRIPT...........................................................................................................61
6 DISCUSSION.............................................................................................................83 7 REFERENCES...........................................................................................................89
8 APPENDICES ..........................................................................................................103
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LIST OF TABLES
Table 2-1. Institute of Medicine (2001) reported absolute requirements and Dietary Reference Intakes (DRIs) for iron in male and female infants, children and adults. ...32
Table 2-2. Summary of prevalence studies in anemia and iron deficiency for Inuit and northern First Nations children, and comparison groups.a..........................................33
Table 2-3. Estimated iron content of some traditional Inuit foods and market foods.......34
Table 2-4. Summary of reported prevalence rates of Helicobacter pylori infection in northern or Arctic regions, and in comparison groups. ..............................................35
Table 4-1. Nunavut communities, location and population sizes. ...................................58
Table 4-2. Inuit Child Health Survey 2007-2008 data collection schedule......................59
Table 4-3. Descriptions of measured outcome and exposure variables. ..........................60
Table 5-1. Population and household characteristics. .....................................................76
Table 5-2. Summary of serum ferritin and hemoglobin concentrations for Nunavut and by region. ......................................................................................................................77
Table 5-3. Prevalence of iron deficiency, anemia, iron deficiency anemia and Helicobacter pylori infection among participating children.......................................78
Table 5-4. Mean, median and percentage of individuals with intakes below the EAR, not including supplements, for energy, vitamin C and iron in Inuit children, ages 3 to 5 years (n = 374)..........................................................................................................79
Table 5-5. Frequency of consumption of traditional and market food sources of iron among Inuit children, ages 3 to 5 years. ....................................................................81
Table 5-6. Bivariate analyses of explanatory factors for iron deficiency and iron deficiency anemia using two different ferritin cut-off values to define iron deficiency..................................................................................................................................82
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LIST OF FIGURES
Figure 2-1. Map of Inuit regions and communities in Canada. .......................................36
Figure 2-2. Age-sex pyramid of the predominantly Inuit population in Nunavut and the total population of Canada, 2006 [6]. ........................................................................37
Figure 5-1. Adjusted iron intake distribution for Inuit children, aged 3 to 5 years, in Nunavut. The Estimated Average Requirement (EAR) for children aged 3 years is 3.0 mg and for children 4 to 5 years is 4.1 mg.................................................................80
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LIST OF APPENDICES
Appendix A. Quality control material for dietary questionnaires..................................104
Appendix B: Clinical protocols and quality control procedures for clinical equipment.107
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LIST OF ABBREVIATIONS
AGP alpha-acid glycoprotein AI Adequate Intake CI Confidence interval CRP C-reactive protein CV Coefficient of variation DMT1 Divalent metal transporter 1 DRI Dietary Reference Intakes EAR Estimated Average Requirement ELISA Enzyme linked immunosorbant assay FPN1 Ferroportin 1 FFQ Food frequency questionnaire GI Gastrointestinal Hb Hemoglobin hsCRP High sensitivity C-reactive protein ICHS Inuit Child Health Survey IDA Iron deficiency anemia IDE Iron deficiency erythropoiesis IOM Institute of Medicine IREG1 Iron regulated transporter 1 KHAS Keewatin Health Assessment Survey NCNS Nutrition Canada National Survey NHANES National Health and Nutrition Examination Survey OD Optical density PR Prevalence ratio RDA Recommended Dietary Allowance RR Relative risk SF Serum ferritin sTfR Serum transferrin receptor TIBC Total iron binding capacity TS Transferrin saturation UBT Urea breath test UL Tolerable Upper Intake Limit USDA United States Department of Agriculture WHO World Health Organization
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1 STUDY BACKGROUND
1.1. ABORIGINAL PEOPLES AND INUIT IN CANADA
There is no internationally recognized definition of Indigenous Peoples but it is generally
agreed that they are a group of people who are native to the land [1]. It is generally
accepted that around 15,000 years before present, the Indigenous group known today as
the Inuit, migrated across the Bering Strait, settling in the circumpolar regions of the
Russian Chukotka peninsula, central and south-western Alaska, northern Canada and
Greenland [2]. Inuit, with First Nations and Dene/Métis, make up three distinct
Indigenous, or Aboriginal groups in Canada [3, 4]. In Canada, Inuit predominantly live in
four distinct regions that make up Canada’s northern-most lands (Figure 2-1). These are
Nunavik in northern Quebec, Inuvialuit Settlement Region in the Northwest Territories,
Nunatsiavut in Labrador, and finally Nunavut, the area where the following study took
place.
Political borders once defined Nunavut as part of the Northwest Territories but this
changed with the 1993 Nunavut Act when it became Canada’s third distinct territory.
Situated in north-central Canada, Nunavut’s borders range from 56º N to 76º N in latitude
and from 64º W to 115º W in longitude. Within Nunavut there are three regions, Kivalliq,
Baffin and Kitikmeot and 25 settled communities. All of these communities are Hamlets
except for Iqaluit, which is the only city in the territory, the capital of Nunavut and the
most populated area (Figure 2-1).
Eighty-four percent of Nunavut’s total population are Inuit. The remaining population
is of other Aboriginal identity (1%) or non-Aboriginal (15%) [5]. The total population in
Nunavut is 51% male [6]. Among all children under the age 5 living in the territory, 92%
are Inuit [5]. Approximately 11% of the total Nunavut population is under the age of 5,
compared to approximately 5% overall in Canada [6], (Figure 2-2).
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1.2. HEALTH CARE DELIVERY IN NUNAVUT
Within each Nunavut hamlet there is a health centre staffed with at least two full-time
nurses and with on-call after hours service. The only hospitals in Nunavut are found in
the capital city, Iqaluit. Most hamlet health centres are equipped to provide neo-natal
care, minor surgery, x-ray, in-patient care and commonly needed prescription medicines
and vaccines. Tele-health technology is available and allows for audio-visual long-
distance conferencing between health centres in Nunavut and in major Canadian cities.
Physicians and dentists are available full-time in some communities while others are
visited for a few weeks at a time. If a community member requires medical attention that
cannot be provided by the local health centre they are flown to Iqaluit or a major
Canadian city for care. Regarding child health specifically, health centres routinely
provide vaccinations and preschool screenings. Preschool screenings include vision and
hemoglobin testing and growth monitoring. Child and infant vitamin and mineral
supplements such as iron, vitamin D, fluoride and multivitamin supplements are available
through health centres. The costs of these and most prescription medications are covered
by government-provided public health insurance.
1.3. INUIT CHILD HEALTH SURVEY
The project “Iron deficiency and iron deficiency anemia among preschool aged Inuit
children living in Nunavut” is one component of a broader child health survey. Known as
the Inuit Child Health Survey (ICHS), this comprehensive cross-sectional health survey
of preschool Inuit children, ages 3 to 5 years, living in Nunavut looked at various health
indicators in addition to iron status. Further, the survey is a component of a broader
survey called “Qanuippitali? How about us, how are we?”, which includes adults as well
as children. Data collection for Qanuippitali? took place in 2007 and 2008. The adult
health survey was larger in scope than the child health survey. It included data collection
in 39 communities in Inuvialuit Settlement Region, Nunavut and Nunatsiavut and
employed the use of a Coast Guard ice-breaker vessel to travel to communities and
conduct research activities. The ICHS was land-based, taking place in 16 Nunavut
communities, independent of the ship-based adult survey.
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2 LITERATURE REVIEW
Iron is a nutrient that is essential for growth and proper function of many organ systems.
When iron requirements are not met, it is generally referred to as iron deficiency. Iron
deficiency can develop in men and women, boys and girls and at any age. Within each of
these groups, there may be differing etiologies and health outcomes. This chapter begins
with a general review of iron metabolism and requirements. The Inuit context is then
emphasized with a review of previous research in childhood iron deficiency in
circumpolar populations. It will be shown, however, that there is a research gap for Inuit
preschoolers in Canada. The final sections of this chapter describe potential risk factors
for iron deficiency, again, as they relate to Inuit children.
2.1. IRON METABOLISM, REQUIREMENTS AND DEFICIENCY
2.1.1. Iron metabolism
Iron is an essential nutrient that must be obtained from the diet and absorbed in the upper
gastrointestinal tract (GI). Iron requirements change depending on sex and life stage and
in order to understand these requirements, it is necessary to first understand the
mechanisms by which iron is absorbed, circulated and utilized by different cells.
There are two forms of dietary iron: non-heme and heme iron. Non-heme iron takes
the more simple form of free iron atoms, such as ferric (Fe3+) or ferrous (Fe2+) iron.
Non-heme iron is ubiquitous in many foods such as grains, pulses, legumes, fruits and
vegetables. In most populations throughout the world, non-heme iron is the main form of
dietary iron [7, 8]. Heme iron is a more complex form of iron and is available only from
animal meats and organs.
When either form of iron is consumed, it is absorbed from the upper regions of the
small intestine. In the acidic environment of the stomach, non-heme ferric iron (Fe3+) is
reduced to ferrous iron (Fe2+) [7, 9-12]. If this reduction reaction has not occurred by the
time ferric iron reaches the small intestine, the DcytB brush border enzyme converts iron
to its ferrous state [7, 9-12]. The divalent metal transporter 1 (DMT1) transports ferrous
4
iron across the luminal membrane of enterocytes lining the duodenum or upper jejunum
[7, 9-12]. Once inside the enterocyte, ferrous iron may be stored in the main iron storage
protein, ferritin, or directly exported out of the cell and into the portal vein [7, 9-12].
Ferritin stores iron in many cells and is a 24-subunit protein with a central cavity that can
hold up to 4500 iron atoms [13]. If iron is not immediately needed, it remains stored in
the enterocytes and is excreted when they are sloughed off [7, 9-12]. When iron is
needed, the protein transferrin transports ferrous iron to the basolateral side of the cell [7,
9-12]. Iron is then transported across the cell membrane via ferroportin 1 (FPN1) also
known as iron-regulated transporter 1 (IREG1) [7, 9-12]. Hephaestin, a ferroxidase
enzyme found on the basolateral cell membrane, oxidizes iron to its ferric (3+) state to
allow for transport through the circulation [7, 9-12].
The above describes non-heme iron absorption and heme iron absorption differs. As
mentioned, heme iron is derived from animal meats and organs, but more specifically is
derived from hemoglobin, an oxygen transport protein characteristic of red blood cells,
and from myoglobin, an oxygen storage and transport protein in muscle [14].
Hemoglobin is a tetrameric protein made up of four subunits [14]. Each subunit consists
of a globin protein bound to a heme molecule made up iron-protoporphyrin ring complex
[14]. Myoglobin is similar in structure but consists of a single heme-globin subunit [12].
When meats or organs are consumed, heme molecules are split from globin in the
small intestine [10]. The iron-protoporphyrin complex is transported into the enterocyte
via a heme transport protein [10]. Once inside the enterocyte, a hemooxygenase enzyme
releases ferrous (2+) iron from the porphyrin ring at which point, the free iron has a
similar fate as free non-heme iron entering the enterocyte [10].
Once released into the blood stream, iron is handled and used in different ways. Iron is
transported bound to transferrin to various cells. Inside cells, iron may be stored or used
as functional iron to create iron-containing proteins [7, 15]. The majority of functional
iron is contained in hemoglobin which is further incorporated into red blood cells in the
bone marrow [15]. As described above, each hemoglobin protein contains four iron-
protoporphyrin rings. The presence of these rings in hemoglobin allows for erythrocytes
5
to reversibly bind oxygen for transport and delivery to tissues throughout the body [12].
In addition, when carbon dioxide concentrations are high, hemoglobin preferentially
binds carbon dioxide and delivers it to the lungs for excretion [12].
Functional iron is also found in myoglobin which stores and transports oxygen in
muscle tissue [12]. Iron containing proteins called cytochromes are involved in electron
transfer reactions that occur in mitochondria as part of cellular energy production [12]. In
addition, iron is a component of enzymes involved in non-water soluble drug excretion,
DNA synthesis, synthesis of certain neurotransmitters and synthesis of myelin which
surrounds certain neurons and aids in signal transduction [12, 15].
When iron is not needed for the various functions described above, it is stored. Storage
iron is found in all cells but mostly in the liver, bone marrow and spleen [7, 15]. Zero to
50% of the body’s total iron may be in storage, either bound to ferritin or hemosiderin
within cells [15]. In the liver, hepatocytes take up iron mostly from circulating iron bound
to transferrin and release it back into the circulation when needed by tissues [16].
In healthy human beings, iron loss is minimal except through menstrual blood loss in
women and girls. Iron is recycled from proteins by macrophages and liver Kuppfer cells
[15, 16]. For example, these cells perform phagocytosis of senescent, or deteriorating,
erythrocytes [17]. Macrophages and Kuppfer cells remove iron from bound protein and
recycle it back into circulation to be picked up by transferrin and re-used [17]. This
process of iron recycling in addition to the low solubility of iron in water results in
minimal excretion of iron [15]. Some daily iron loss does occur through enterocyte
shedding, bile excretion, urine and the skin [12].
2.1.2. Iron requirements and measuring dietary intake
Iron is required from the diet in general to replace daily losses. In infants, children and
adolescents, iron is also required to meet the needs of growth and development. There
exists a set of age and sex specific iron requirements that describe absolute daily required
iron, that is, the amount that needs to be absorbed from the diet [18], (Table 2-1). Only a
portion of consumed iron will be absorbed and the remainder will be lost through
6
excretion from the GI tract. The absorbed portion is said to be bioavailable. As such, the
Daily Recommended Intakes (DRIs), which are used by health researchers and
professionals to assess dietary iron intake, take into account both the body’s absolute
need for iron at the various life stages, as well as limited iron bioavailability.
Iron has low bioavailability because it is not readily absorbed and the presence of
other foods in the diet may inhibit absorption [7]. For example, 25% of heme iron is
absorbed from a meal [7]. Dietary calcium, high cooking temperatures and lengthy cook
times are reported to impair heme iron absorption in the gut [7]. About 5 to 15% of non-
heme iron is thought to be bioavailable depending on the presence of iron absorption
enhancers and inhibitors in the diet [7, 8]. Inhibitors of iron absorption include phytates
found in cereals, grains, nuts, seeds, vegetables, roots and fruit, phenolic compounds
found in tea and coffee, calcium and soy protein [8, 19]. Enhancers of iron absorption
include ascorbic acid and the presence of meat, fish or poultry in the diet [8].
The DRIs include the recommended dietary allowance (RDA), the estimated average
requirement (EAR), adequate intake (AI) and the tolerable upper intake level (UL). The
RDA is the amount of a given nutrient that when consumed, is anticipated to meet the
needs of 97.5% of the population [7]. The estimated average requirement (EAR) is the
amount of a given nutrient that will meet the needs of 50% of the population [7]. The
EAR and RDA for iron are set at levels that are thought to maintain iron needs without
creating too much storage iron [7], (Table 2-1). The EAR and the RDA were determined
based on a mixed North American diet, in which dietary iron is approximately 90% non-
heme iron and 10% heme iron, resulting in an overall 18% bioavailability of iron [7]. As
can be seen in Table 2-1, when accounting for low bioavailability, the DRIs for iron are
much higher than the absolute requirement.
When there is insufficient evidence to establish an EAR for a nutrient, the adequate
intake (AI) is given instead. The AI is the observed or experimentally determined amount
of a nutrient that is consumed in a healthy population [7]. For iron, an AI is given for
infants aged 0 to 6 months and reflects the average amount of iron in breast milk (Table
2-1). Healthy term infants are born with iron stores and these in addition to breast milk
7
meet the infant’s iron needs until 4 to 6 months of age [11]. Beyond this iron from other
dietary sources is needed [11]. The tolerable upper intake level (UL) is the highest limit
of intake that is likely to pose no risk of adverse health outcomes for most people [7]. For
iron, the UL was determined based on evidence of gastrointestinal effects such as nausea,
vomiting and diarrhea at intakes more than 70 mg/day [7]. This was lowered to 40 to 45
mg/day to allow for a certain level of uncertainty with respect to the UL for iron [7].
The IOM recommends that only the EAR be used to assess the nutrient intake of
individuals and populations [18]. Further, using the EAR in dietary assessment involves
taking intake account the day-to-day variability in nutrient intake (i.e. one cannot simply
compare observed intake to the EAR) [18]. Overall, the EAR is used to estimate
probability of adequate intake in individuals and populations [18]. The EAR is just a
guideline to aid in determining the risk of inadequate intake. It is not a cut-off value that
can classify people with intakes below the EAR as having inadequate intakes. Recall that
in a healthy population, 50% of people will have iron needs below the EAR. The RDA is
published as a target usual intake for individuals, but should not be used to assess the
intake of individuals or populations [18].
One of the challenges of applying the DRIs is accurately measuring dietary intake.
Different tools that can be used for this purpose include observation, food records, food
frequency questionnaire and 24-hour dietary recalls [20, 21]. Each of these can provide
an estimate of dietary intake, however, the information differs within each and each has
its strengths and weaknesses, especially with respect to its estimation of usual diet, which
varies from day to day.
Dietary records require a participant to keep a quantitative record of all foods eaten
within a specified period of time [21]. The dietary food record is typically done from 3 to
7 days and is considered a gold standard in dietary assessment [21]. Food records are
advantageous because diet is recorded at present time and does have to be recalled,
leaving less room for missing or forgotten information [21]. When many days of diet are
recorded, dietary records can provide an estimate of usual diet for the individual [21].
However, food records impose participant burden and perhaps measurement bias if
8
participants change their usual diet because they are keeping a record of it. In addition,
food records are inappropriate for young children. As such, food records are usually
inappropriate for large epidemiological studies especially where time constraints are an
issue.
Food frequency questionnaires (FFQs) ask a participant to recall their usual diet over a
longer period of time and are advantageous because they can be completed rapidly
relative to food records while still providing an estimate of usual intake [20, 22]. FFQs
are limited in that they only contain a list of foods and foods not listed are likely missed.
As such, FFQs need to be developed carefully and often validated to ensure the
appropriate foods are included. In addition, in order to estimate usual nutrient intake from
an FFQ, one needs quantitative information about each food listed, that is, the typical
portion size and frequency of consumption. This requires participants to recall this
information and is likely less accurate than quantitative information from a food record
[21]. In addition, when they are long, FFQs can impose burden on the participant. While
FFQs are thought to provide better estimates of usual intake for an individual than 24-
hour dietary recalls, which are discussed below, they can also be logistically difficult
[21].
The 24-hour dietary recall method is commonly used and has been shown to be valid
for short-term intake for preschoolers [23]. Validation studies typically involve
comparing 24-hour recall data to observed of dietary intake [23]. The 24-hour recall
method involves an interview to record detailed, quantitative information about the foods
and drinks consumed by the participant for a 24-hour period. A five-step multiple pass
interviewing method is typically used and has been previously validated for many
nutrients [24].
Twenty-four hour recalls are advantageous because they can obtain quantified dietary
information rapidly [22, 25, 26]. However, one recall can only provide short-term dietary
information, and unlikely information about an individual’s usual diet [22, 25, 26]. With
respect to iron specifically, this is reflected in low correlations between 24-hour recall
9
intake data and iron status biomarkers [7, 25, 26]. As such, multiple recalls on varying
days are required to assess usual individual intake [22].
2.1.3. Health outcomes of iron deficiency
Iron deficiency varies in severity and is generally classified into three stages. The mildest
stage of iron deficiency is iron depletion where there is a decrease in iron stores, such as
those in the liver [20]. Iron deficiency erythropoiesis (IDE) is slightly more severe. It is
characterized by depleted iron stores, decreased iron supply to the tissues but no observed
effect on circulating erythrocytes [20]. Finally, iron deficiency anemia (IDA) is the most
severe stage of iron deficiency. It occurs when there is a lack of iron to synthesize
hemoglobin and hence, healthy erythrocytes [20]. In IDA, erythrocytes appear small and
pale, otherwise known as hypochromic, microcytic anemia [14, 20].
Anemia is not always hypochromic and microcytic or always a result of iron
deficiency. Anemia occurs when there is a severe enough reduction in erythrocyte mass
or in blood hemoglobin concentration [14]. In addition to iron deficiency, there are
numerous other causes of anemia in children including disorders involving the bone
marrow, impaired erythropoietin production, disorders impairing erythroid maturation
and hemolytic anemias [14]. These are beyond the scope of this review, but are important
to recognize since it is estimated by the WHO that world-wide that only 50% of observed
anemia is related to iron deficiency and the remainder is related to other causes [27].
Childhood is a vulnerable age for iron deficiency because children have rapid growth
and a subsequent high requirement for iron relative to body mass [8]. Iron deficiency is of
particular concern in children because they are undergoing growth and development and
these processes can be impaired in the presence of iron deficiency. For example, IDA can
lead to impaired cognitive development and neurological malfunction, fatigue and growth
delay [7, 12, 15, 20, 28]. Further, treatment with iron therapy is not necessarily able to
reverse the effect of cognitive impairment later in life, resulting in behavioural and
developmental problems [29, 30]. IDA can also result in impaired resistance to infection
specifically decreased leukocyte killing and decreased cells available for cell mediated
10
immunity [15, 28]. Severe IDA with hemoglobin less than 50 g/L can lead to respiratory
distress, congestive heart failure, and, rarely, cardiac arrest [30].
The above health outcomes were observed only in children with IDA, and it is unclear
if milder stages of iron deficiency result in developmental deficits [28]. Some studies in
infants have reported that cognitive development and motor deficits are seen even with
iron deficiency without anemia [15, 30]. In the United States, school-aged children with
iron deficiency but not anemia had lower math scores than children with healthy iron
status [31]. Other studies have reported reduced aerobic or work capacity in adults with
iron deficiency but not anemia [32, 33].
There are numerous causes of iron deficiency and IDA in children. They are briefly
reviewed here, but those more relevant to Inuit children will be reviewed in more detail
later. Celiac disease or inflammatory bowel disease can result in inflammation and
damage to the intestinal epithelium, which can impair iron absorption [14]. The presence
of phytates, polyphenols, calcium or soy protein may also limit iron absorption in
addition to lack of heme-iron or ascorbic acid in the diet [8, 19]. Gastrointestinal blood
loss can also result in iron deficiency. This may be a result of anatomical defects in the
gastrointestinal tract and bleeding peptic ulcers [14]. Microscopic blood loss from the
gastrointestinal tract may result from inflammation, cow’s milk consumption before the
first year of life, and parasitic infection with hookworm or whipworm [14]. In young
children and infants in particular, in the absence of parasitic infection or chronic
gastrointestinal illness, iron deficiency is usually related to low dietary iron intake,
particularly prolonged breast-feeding and high cow’s milk consumption, both of which
can replace iron-rich foods [34]. Evidence has also emerged that infection with the
human pathogen Helicobacter pylori (H. pylori) can cause iron deficiency in young
children as well as adults. H. pylori as well as dietary risk factors in relation to Inuit
children will be discussed in more detail later in this review.
Causes of general anemia, as opposed to IDA, is not the focus of this study but it
should be mentioned that there are various processes that can result in low hemoglobin or
erythrocytes in children. Vitamin A, riboflavin, folic acid, vitamin B-12 and vitamin B-6
11
are required for normal erythrocyte production [35, 36]. As such, deficiency in any of
these may result in anemia, even if iron stores are normal. Although less significant, it
has been suggested that the anti-oxidant properties of vitamins C and E are important in
maintaining hemoglobin levels since they protect against free radical destruction of
erythrocytes [35]. Acute infection and inflammation can also lead to anemia in children.
The inflammatory response leads to an increase in certain cytokines that block the
movement of iron from cell to cell [17]. For example, macrophages that recycle iron from
senescent erythrocytes can no longer move iron back to the tissues in the presence of
inflammation [14, 35-37]. In addition, oxidative stress causes lyses of senescent
erythrocytes thus reducing the concentration of hemoglobin in the blood [17]. The end
result may be mild anemia with normal iron stores.
Overall, the health consequences of IDA are severe in children and potentially
irreversible. As such researchers and health organizations have conducted studies to
measure the prevalence of iron deficiency and IDA in children for decades. Inuit have
been the subject of some of this research for almost 40 years now. After reviewing the
methods for measuring iron status, the next section will provide a review of population-
based research in iron deficiency. The focus will be Inuit children, and as will be shown,
it is reasonable to suspect that rates are high compared to American children. Also, there
is a need for current information on this important issue in preschool aged Inuit children.
2.2. POPULATION-BASED RESEARCH IN IRON DEFICIENCY
2.2.1. Measuring iron status
The currently accepted method for assessing prevalence of iron deficiency is to
measure concentrations of biomarkers in blood samples. Various biomarkers can be used
and each can provide information about the severity of iron deficiency.
Hemoglobin or hematocrit concentrations in the blood are used to assess anemia
irrespective of iron status [20, 28]. Hemoglobin concentrations less than 110 to 115 g/L
are indicative of anemia in children [20, 28]. Hemoglobin can be measured with an
automated Coulter counter system in a clinical or laboratory setting, or using portable
12
haemoglobinometer called HemocueTM [20]. Blood samples are inserted into the
HemocueTM in specially manufactured cuvettes that haemolyse free hemoglobin and
convert it to a measurable form called azidemethaemoglobin, which is measured via light
absorbance [38]. HemocueTM is reported by the manufacturer to be accurate within ± 3
g/L of hemoglobin and studies have confirmed it’s accuracy for clinical and research use
using venous and capillary blood samples [39-41]. However, one study reported larger
variations in repeat test results with capillary blood samples than when using venous
blood [42]. Another study reported that capillary samples showed higher results than
venous samples but the difference was not significant [43]. They also showed low
coefficients of variation (CVs) with repeat capillary samples. It seems overall that there is
ample evidence supporting the accuracy and precision of the HemoCueTM method of
measuring hemoglobin concentration, and this tool is recommended by the World Health
Organization (WHO).
Anemia can also be assessed by measuring hematocrit, which is the volume fraction of
red blood cells in a blood sample [20]. When hemoglobin synthesis is reduced,
hematocrit also becomes reduced [20]. It can be measured by calculating the ratio of
packed red cell height to total sample height or using an automated coulter counter [20].
Hematocrit fraction less than 0.33 or 0.34 is indicative of anemia in children [20].
Measuring hematocrit is limited because it is prone to measurement error and can be
affected by high white blood cell counts [20]. Overall, hemoglobin is a more sensitive
measure of anemia since hemoglobin concentration tends to drop before reduced
hematocrit can be detected [20].
Low hemoglobin or hematocrit measurements indicate anemia, but other biomarkers
are required to assess iron deficiency specifically. The status of iron stores can be
measured via plasma or serum ferritin [20, 28]. Ferritin within cells stores iron but ferritin
is also present in the circulation, where it serves as an acute phase protein produced by
liver [20, 28]. It correlates well with total body iron stores and low serum ferritin levels
indicate low or depleted iron stores [20, 28]. It has been proposed that serum ferritin less
than 12 µg/L indicates storage iron deficiency in young children [20, 28]. The National
Health and Nutrition Examination Survey (NHANES) III, a large longitudinal study in
13
the United States, used a lower cut-off of 10 µg/L for children [44]. This cut-off value
has also been used in some Canadian studies with infants [45, 46]. Another study
suggests that ferritin less than 5 µg/L be used to identify iron deficiency in 9 month old
infants [47]. Serum ferritin can be measured in serum or plasma samples using an
immunoradiometric assay or an enzyme linked immunosorbance assay [20, 28]. A
method of measuring ferritin in dried blood spots has also been recently developed [48].
Plasma or serum ferritin values are of limited use during infection because they may
become falsely elevated with the acute phase response. As such, ferritin results should be
interpreted with a biomarker of acute infection status such as C-reactive protein (CRP) or
alpha1-acid glycoprotein (AGP). CRP is an acute phase protein made up of five identical
subunits [49]. It plays a crucial role in pathogen killing, removal of damaged apoptotic
cells and complement activation [49]. When infection occurs, CRP concentrations
quickly rise, but also quickly decline 24 to 48 hours after stimulation [50]. AGP
concentrations remain elevated for 5 to 6 days and ferritin remains elevated for up to 10
days [50]. As such, in the presence of elevated CRP or AGP, ferritin values should be
interpreted with caution. As is the case with ferritin, the cut-off values for CRP are
unclear. Some researchers use higher cut-off values for CRP, such as 8 ng/mL and 10
ng/mL to indicate infection [51, 52]. Others use lower values, such as 3 ng/ml or 2 ng/ml
[50, 53].
Low ferritin only indicates early stages of iron deficiency. When coupled with a
measure of hemoglobin, IDA can be assessed. However, more moderate stages such as
IDE cannot be determined from these measures. Transferrin saturation can be used to
assess whether iron deficiency as defined by low serum ferritin has progressed to IDE.
Transferrin saturation is a measure of the ratio of serum iron to total iron binding capacity
(TIBC) [20, 28]. In IDE, serum iron decreases and TIBC increases [20, 28]. As such,
very low transferrin saturation indicates nutritional iron deficiency that affects tissue iron
supply [20, 28]. Transferrin saturation is useful because when it is at the low end of
normal range, it indicates infection since serum iron is decreased, but TIBC does not
increase as it does in nutritional iron deficiency [20, 28]. In children, transferrin
saturations below 10 to 14% have been proposed as cut-off values, but are unclear since
14
serum iron changes with age [20, 28]. Serum iron is measured using a clinical chemistry
autoanalyzer and TIBC is determined by measuring the amount of iron required to
saturate transferrin [20, 28].
Erythrocyte protoporphyrin also measures IDE and specifically indicates decreased
iron supply for erythrocyte synthesis. It becomes elevated when iron levels are
insufficient to produce heme for erythrocyte protoporphyrin [20, 28]. This method is
limited because it is falsely elevated during infection, lead poisoning and haemolytic
anemia [20, 28]. Erythrocyte protoporphyrin can be measured in a research setting using
fluorescence or haematofluorometer [20, 28].
Serum transferrin receptor (sTfR) is another biomarker that can be used to assess IDE.
If iron deficiency is severe enough and supply to tissues is limited, sTfR levels in the
blood increase, reflecting the up-regulation of cellular transferrin receptors to capture
more iron in the tissues [20, 28]. Elevated levels of sTfR indicate tissue iron deficiency,
but cut-off values are unclear, even for adults [20, 28]. Serum TfR is useful because it is
not influenced by infection and recent studies have shown that the ratio of sTfR to serum
ferritin can distinguish between low circulating iron due to nutritional iron deficiency and
that due to infection and inflammation [54, 55]. Serum transferrin receptor can also be
measured in small volumes of serum [20, 28].
There are numerous biomarkers of iron deficiency and anemia, each with their
strengths and limitations. Overall, biomarkers exist to measure every stage of iron
deficiency. The WHO suggests that in a population-based research setting, the ideal
combination of biomarkers for measuring iron status is hemoglobin, plasma or serum
ferritin coupled with a marker of infection and serum transferrin receptor [28]. This
allows one to assess all stages of iron deficiency using biomarkers that can reasonably
measured for large groups of people.
2.2.2. Iron deficiency among Inuit children: review of prevalence estimates
Some information is available on the iron status of Inuit children, although more recent
studies focus more on infants or Alaska Native children. However, these and results from
15
the latest nation-wide nutritional survey in Canada will be reviewed below to show that
the prevalence of iron deficiency is typically higher among Inuit compared to non-
Aboriginal groups. In addition, information for Nunavut preschoolers currently is not
available.
One problem with many of the studies that investigate childhood iron deficiency
among Inuit is that rates for preschoolers are not reported separately than those for
infants. This makes it difficult to truly know about the iron status of Inuit preschoolers
since infants tend to have higher rates of iron deficiency. This difference between age
groups was seen in the 1995 Keewatin Health Assessment Survey (KHAS) where anemia
was found in 11.5% of Inuit aged 9 months to 17 years but then was much higher at 27%
in only those aged 9 months to 2 years [56]. Similarly, among Northwestern Ontario First
Nations children, those aged 3 to 30 months had rates of anemia of 38% to 79%, but
preschoolers aged 30 to 60 months had lower rates of 12 to 28% [57]. Among Alaska
Natives a similar trend is seen where among children aged 0 to 5 years iron deficiency
was found in 70% and anemia in 17% [58] . Then, among older children of 7 to 11 years,
iron deficiency was found in only 38% and anemia in 15% [59].
As such, data for age groupings including both infants and preschoolers need to be
interpreted carefully. For example, the most recent data on the iron status of Canadian
preschoolers comes from the 1970-1972 Nutrition Canada National Survey (NCNS), but
these children are grouped with infants [60]. Anemia from all causes was around 4 to 5%
for both Inuit and non-Aboriginal children aged 0 to 4 years [60]. IDE was detected in
5% of non-Aboriginal children and in 12% of Inuit children [60]. From these results, one
cannot whether Inuit infants are more at risk for IDE, or preschoolers, or perhaps both.
Although the NCNS only included 29 Inuit children from the Kivalliq region and did
not separate children from infants, it suggests that Canadian Inuit are at higher risk than
the general popualation. A later study assessed iron status of Inuit in the high Arctic [61].
Here, IDE was 3 to 7%, but again, the authors did not report age specific rates so it is
difficult to derive conclusions for preschoolers [61]. In addition, because the NCNS only
measured transferrin saturation and hemoglobin, a sub-sample of serum was analyzed for
16
ferritin, but not for Inuit [62]. Among this sub-sample, iron deficiency was found in 30%
and IDA in 2%. Given that the rate of IDE was higher among Inuit, it is possible that
rates of iron deficiency among Inuit children 0 to 4 years were higher than 30% and those
of IDA were higher than 2%. However, this is merely speculation and overall, the latest
information on the iron status of Canadian Inuit is outdated with a small sample size and
inappropriate age groupings.
More recent studies are available for Canadian infants and seem to show a continued
trend that Inuit are at higher risk for iron deficiency. Among Inuit infants from Nunavut
and Nunavik, iron deficiency was found in 37 to 60% compared to about 33% in non-
Aboriginal Canadian infants [45, 46, 51]. IDA was found in about 26% compared to
about 5% in non-Aboriginal Canadian infants and 24% in low-income Montréal infants
[45, 46, 51, 63]. Anemia from all causes was found in 37% to 48% compared to 8% in
non-Aboriginal Canadian infants [45, 46, 51].
A similar trend was seen among Alaska Native children aged 0 to 5 years where the
prevalence of iron deficiency was 70% and among children 7 to 11 years, the prevalence
of iron deficiency was 38% and IDA was 7.8% [58, 59]. In the United States, iron
deficiency rates are much lower than this. Recent data from NHANES (1999-2000)
showed that among children 3 to 5 years, 0.5% had IDA and among children 6 to 11
years, 0.1% had IDA [64].
From reviewing studies in iron deficiency among Inuit, it is revealed that current
information has not been reported for Inuit preschoolers in Canada. While some estimates
exist from the 1972 NCNS, they are for both infants and preschoolers together so age-
specific rates were not available. It was explained above that infants typically have higher
rates of iron deficiency, IDA and anemia than children in older age groups. As such, it
may be hypothesized that Inuit preschoolers experience rates of iron deficiency less than
36 to 60% and IDA less than 26%, which are current estimates for Inuit infants.
However, while preschoolers may have lower rates than infants, data from Inuit
populations compared to non-Aboriginal population suggests that Inuit have higher rates
17
than the national population. The uncertainties around this issue in addition to the
detrimental health outcomes of IDA precedent the need to fill this information gap.
2.3. ETIOLOGY OF IRON DEFICIENCY AND ANEMIA AMONG CHILDREN
2.3.1. Overview of causes of iron deficiency and IDA in children
Various causes of iron deficiency in children were mentioned above and the final section
of this review will discuss some of these in detail as they relate to Inuit children. As
mentioned previously, bleeding from the GI tract due certain parasitic infections may
result in iron deficiency in children. There is no evidence that these particular parasites
exist in the Arctic. Iron absorption impairment and microscopic bleeding resulting from
inflammatory bowel or celiac disease is possible in Inuit children, but is unlikely to
explain large prevalence rates of iron deficiency and IDA should they exist in this
population. In addition, genetic factors leading to IDA or hemoglobinopathies are
possible, but again, unlikely to explain any large prevalence rates of this condition. The
main causes of iron deficiency in Inuit children may be related to the diet and infection
with the common human pathogen H. pylori.
2.3.2. Dietary factors related to iron deficiency
Young children rely on iron from the diet to meet their growing needs. When they
consistently have iron intakes below their needs, it can result in iron deficiency or IDA.
The issue of iron deficiency among Inuit has been described as a paradox because the
traditional Inuit diet consists of numerous sources of land and sea animal meats and their
organs (Table 2-3). Assuming that children are eating a traditional diet, one would
suspect that the risk of inadequate iron is low. However, as explained above, previous
studies report that iron deficiency exists in Canadian and Alaskan Inuit, and that these
rates are higher than national averages. This seeming paradoxical trend may be explained
by a nutrition transition that has likely been occurring in Arctic communities since the
early 20th century [2].
18
In the late 1970s in a remote Inuit community it was reported that 75% of Inuit
households were using commercially available market food “half of the time” or “most of
the time” while still hunting caribou and seal [65]. Other studies report similar trends
where market food continues to make up some proportion of the Inuit diet [66-68]. In
addition, although there are many sources of iron in market foods such as meats and
cereal grains, as shown in Table 2-3, some of these foods with limited shelf life may be
expensive or less available in remote communities [68, 69]. In addition, studies with
Canadian Inuit and Dene/Metis show that diets high in market foods are also higher in
simple carbohydrates and fat [70, 71]. This transition from traditional foods towards
market foods, particularly those that are less micro-nutrient rich, and high in simple
sugars and fat, is known as the nutrition transition and evidence shows that it is occurring
in among Canadian Inuit [56].
Another characteristic of the nutrition transition seems to be that younger Inuit
consume less traditional food than older Inuit [66, 71, 72]. Overall, it has also been
shown that iron intake is lower on days where Inuit traditional food is not consumed or
when traditional food intake is lower [70, 71, 73]. However, despite this, iron intake has
consistently reported to be high among Alaska Native and Canadian Inuit even among
younger age groups [70, 74]. With respect to iron specifically, the 1972 Nutrition Canada
Eskimo Survey found a high median dietary iron intake in four Inuit communities [56].
More recently, in a Kivalliq Inuit community, most were eating above two-thirds of the
RDA and seal and caribou meat were the most common sources of iron among infants
[51].
Studies on Inuit diet consistently suggest that iron intake is likely adequate in the
Canadian Inuit population. However, given that the nutrition transition seems to occur to
a greater extent in younger generations, it is unclear what the situation is like for Inuit
preschoolers today. The most recent study on Inuit iron intake was for infants from only
one community in 2003 and remaining evidence of iron intake comes from studies in the
early 1990s [51, 56].
19
While inadequate dietary iron intake is one potential cause of iron deficiency and IDA,
low dietary iron bioavailability may be another issue. Enhancers and inhibitors of iron
deficiency were discussed previously. The known inhibitors of iron absorption are
phytates, phosphates, calcium, polyphenols and certain dietary fibers. Enhancers include
vitamin C and heme iron consumption. It is unknown to what extent each of these factors
can limit iron absorption since controlled iron intake studies do not reflect habitual iron
intakes [75].
The RDA and EAR for iron assume a dietary iron bioavailability of 18% in a mixed
diet of 90% non-heme iron and 10% heme iron [7]. When these proportions are different,
perhaps the RDA and EAR are not as appropriate. The current recommendation is to
increase the RDA and EAR by 1.8 times in diets verging on 5% bioavailability [7]. The
Food and Agriculture Organization proposes similar adjustments for diets with 5%, 10%
and 15% bioavailability [8]. Other studies have proposed algorithms for determining iron
absorption but in none of these does iron absorption explain differences in iron status [19,
76-78]. Overall, this aspect of the diet is difficult to study and in theory, if the typical
Inuit diet has a dietary iron bioavailability of 18%, the EAR and RDA should be
appropriate reference standards for assessing iron adequacy. If dietary iron bioavailabilty
is thought to be lower, adjustments to the EAR and RDA could be made.
One factor that might require particular consideration is milk consumption. In young
children, cow’s milk consumption is a risk factor for iron deficiency, especially when
introduced at an early age or instead of fortified infant formulas [79]. While it is a rich
source of other essential nutrients, cow’s milk lacks iron and when consumed too much it
tends to replace other food sources of iron [12]. In addition, calcium is an inhibitor of
iron absorption although it is unclear if over the long-term, calcium intake can result in
iron deficiency [80]. Aside from one study in infants that found that cow’s milk
consumption was the only risk factor independently associated with iron deficiency after
controlling for other factors there have been no data reported on milk intake in Inuit
children [51].
20
2.3.3. Helicobacter pylori
H. pylori is a gram-negative spiral bacterium that commonly infects the human stomach
[81]. Barry Marshall and J. Robin Warren won the 2005 Nobel Prize for its discovery in
1983 [82]. It is not known exactly how infection with this pathogen occurs but person-
person transmission is the most likely candidate, as will be discussed. The worldwide
prevalence of H. pylori infection is thought to be around 50% and is typically higher in
low income settings and low overall in higher income such as Canada and the United
Sates. H. pylori is commonly associated with gastric cancer or peptic ulcers. Since it’s
discovery, evidence has emerged that this common pathogen is also associated with iron
deficiency and IDA in adults and children.
Transmission of and risk factors for Helicobacter pylori infection
There is limited evidence supporting zoonotic or water-borne transmission and H. pylori
is most likely transmitted from person to person. Human H. pylori has never been
isolated from pigs, cats or sheep, ruling these out as reservoirs for infection [83].
Monkeys can carry certain Helicobacter species but do not come in contact with enough
people to explain the high world-wide prevalence [83]. In controlled experiments
houseflies were exposed to human H. pylori and have transmitted the pathogen to Petri
dishes but transmission has not been shown to occur when flies are exposed to fresh
human faeces [83].
Regarding water-borne transmission, H. pylori has been found in water supplies such
as lakes, rivers and water delivery trucks, including those in northern regions [84, 85].
However, the bacteria were identified using polymerase chain reaction, which only show
that H. pylori genetic material was present in the water and not viable bacteria.
While the possibility of animal and water reservoirs have not been completely ruled
out, it is generally believed that H. pylori is transmitted form person-to-person through a
fecal-oral or oral-oral route [83]. Viable H. pylori has been cultured from diarrheal
samples, vomitus and also 30 centimeters in the air from vomitus and recent history of
vomiting in siblings was found to be a risk factor for infection [86]. Recent progress in
21
identifying H. pylori specific genetic markers has shown that people living in the same
home tend to carry the same strain, suggesting that person to person transmission
occurred [87].
Even though there remains some uncertainty about the transmission route, certain risk
factors for H. pylori infection have been established. These include lack of hot water
access, household crowding, household age distribution characteristics, socioeconomic
status and race/ethnicity. Retrospectively, 227 adults were asked about their household
living situation when they were 8 years old [88]. Lack of hot water access (OR = 4.34,
95% CI: 1.34-10.0) and more than1.3 people per room relative to less than 0.70 people
per room (OR = 6.15, 95% CI: 1.84-18.6) were associated with H. pylori infection in
adulthood [88]. Among 245 healthy children, aged 3 to 5 years, the prevalence of
infection was higher among those living in low-income homes [89]. Risk factors
surrounding socioeconomic status and race have been reported in other studies [64, 90].
Age has also emerged as a risk factor for infection. In the Colombian Andes where
infection rates are high, the strongest significant predictor of infection in children aged 2
to 9 years was the age gap to the next oldest sibling, where those closer in age were more
at risk [91].
Measuring Helicobacter pylori
There are various diagnostics tests for H. pylori infection and each have their limitations.
The gold standard method is endoscopy, which allows physicians to visually examine the
gastric wall for signs and extent of infection [92, 93]. Children with H. pylori infection
may have healthy looking stomachs and biopsy and culturing for the pathogen can be
used to affirm infection [92]. Endoscopy is performed in a clinical setting, is invasive and
while it has been used on in the research setting, it is not practical in population level
studies. Less invasive and more practical diagnostic tests for H. pylori are antibody
testing, urea breath test or stool antigen testing. Serum or plasma samples can be tested
for IgG or IgA antibodies against H. pylori using commercial ELISAs. This method, also
known as serodiagnosis, is inexpensive and requires only a small volume of blood
sample. However it is limited in children because is cannot distinguish between current
22
and past infection [93]. More importantly, some studies have reported that serodiagnosis
will underestimate the prevalence of infection in children. It is thought that this occurs
because antibody concentrations may take months to increase to detectable levels after
infection occurs [93-95]. One study reported that IgG has a specificity of 54% in children
under 10 years compared to stool antigen testing [95]. In a pilot study in Alaska, 86%
were positive for infection using a urea breath test (UBT) but only 41% were positive
using IgG diagnosis [96]. Where venipuncture is not possible, saliva samples can also be
used for measuring antibodies using commercial ELISAs, but are subject to the same
limitations as serum or plasma antibodies.
Other less invasive tests for infection included the UBT and stool antigen. The UBT
takes advantage of the unique property of H. pylori; the possession of a urease enzyme
that breaks down urea [92]. Patients swallow a pill containing carbon labeled urea. If the
patient has a current infection, labeled carbon dioxide will be detectable in a breath
sample obtained after a fasting period. While there are many reports about the high
accuracy of the UBT, it is has been suggested that there are few studies on UBT in
children so its accuracy in this age group is still unclear [93]. They also suggest that
testing is more costly than other tests and cumbersome in field research setting [93]. H.
pylori stool antigen testing indicates current infection, is lower cost than the UBT, and its
good accuracy has been reported in both adults and children [93]. Where collection of
fecal samples is feasible, H. pylori stool antigen test is reasonable diagnostic test for use
in the research setting.
The gold standard for diagnosing infection remains endoscopy, but this is not feasible
in large studies. Among the less invasive tests in children, UBT and stool antigen testing
seem to be the most accurate however their practicality is limited because obtaining
samples may be difficult [92]. Serodiagnosis is often more practical but is less accurate in
young children and may underestimate the prevalence of infection [93-95].
Prevalence of Helicobacter pylori infection in children
In general, H. pylori infection occurs in childhood and infection prevalence increases
with age [97-99]. Further, in low income countries where risk factors for infection are
23
more common, infection is thought to occur at a younger age than in higher income
countries and as such, infection prevalence is higher in children [97, 99]. For example, in
1991, it was reported that 60% of children in India aged 0 to 9 were positive for infection
while around this same time, only 4 to 5% of children in this age group were positive in
Australia, France and England respectively [99]. Currently in the United States,
prevalence follows the predicted age-related pattern where 5.5% ± 1.4% of young
children aged 3 to 5 years are infected, and peaks at about 30 to 45% in adulthood [64].
In Canada, the prevalence estimate for children aged 5 to 18 years is 7.1%, but they were
selected from children referred for gastrointestinal symptoms and are not representative
of the entire population [100].
Consistent with previous findings for children in low-income settings, H. pylori
prevalence rates are high in Canadian northern First Nations and Inuit communities
(Table 2-4). In Wasagamack, a Cree community in northeastern Manitoba, 56.4% of
children age 6 weeks to 12 years were positive for H. pylori infection in 2002 [101].
Earlier, 95.1% of adults were infected in this community [84]. Among Inuit in two
Kivalliq communities in 1999, the seroprevalence was 50.8% in adults [85]. In 2003, it
was reported that 39% of infants age 4 to 18 months in one Kivalliq community were
seropositive for H. pylori [51]. Using the UBT test, it was found that 86% of Alaskan
Native children, aged 7 to 11 years, were infected by UBT diagnosis [59]. In a younger
age group, the seroprevalence was 32% in Alaskan Native children aged 0 to 4 years
[102]. In addition, the overall prevalence of H. pylori infection among Alaska Natives
was 74.8% and increased with age as occurs in other populations [102]. Overall, it seems
that among Canadian and Alaskan northern populations, the prevalence of H. pylori
infection in young children is 39 to 56%.
In contrast, the prevalence of infection among Inuit children in Greenland was low. In
West Greenland between 1996 and 1998, the seroprevalence was 41% for all age groups
[103]. However, the H. pylori prevalence rate was only 6.1% (95% CI: 0-15.8%) among
children aged 0 to 4 years [103]. In this study, the authors suggest that the lower
seroprevalence compared to other Arctic regions may be due to better housing. They
propose that a birth cohort effect may have occurred in Greenland where the prevalence
24
of H. pylori infection is declining as reflected through low prevalence rates in younger
populations. Similar trends have been seen in other populations in Finland, the
Netherlands and in Germany where infection rates have declined significantly likely due
to improved socioeconomic conditions, decreased household crowding or increased
antibiotic use [104-106].
Evidence suggests the that prevalence of H. pylori infection is high in Canadian Inuit
communities [51, 85]. It further suggests that infection occurs in early childhood and
continues throughout adolescence and adulthood until the overall prevalence in Inuit is
higher than the overall word-wide prevalence [84, 101, 102]. The epidemiological pattern
of H. pylori infection is consistent with that of a low-income setting and as such, young
children may be at risk for H. pylori-related illness such as iron deficiency as will be
discussed next in greater detail.
Pathophysiology of H Helicobacter pylori
An H. pylori bacterium has 4 to 6 flagella that allow it to penetrate the gastric mucous
layer and subsequently adhere to the gastric epithelium [92]. It is not known to penetrate
the gastric epithelium [92]. Bacterial damage to epithelial cells lining the stomach elicits
an immune response, which can lead to chronic inflammation and histological changes in
the gastric mucosa [92]. This is known as gastritis [92]. Gastritis occurs in both adults
and children and its severity varies [92]. Gastritis in children is typically characterized by
immune cell infiltration to the site of infection as well as the presence of lymphoid
follicles [92]. It is typically superficial because the glandular tissue in the gastric
epithelium is undamaged, or intact [92]. More severe forms of gastritis involve atrophy of
the glandular epithelium [92]. In children, metaplasia, which signifies early onset of
gastric carcinoma, and severe gastritis are rare [92]. While the risk ratio of gastric cancer
is 5.9 in infected individuals compared with non-infected individuals, carcinoma usually
only develops in a minority of individuals in the 4th to 5th decade of life [92, 107]. Peptic
ulcer in the stomach or duodenum caused by H. pylori is also rare in children [108]. In
children one symptom of infection may be dyspepsia or pain in the stomach. However
not all H. pylori infection causes dyspepsia and not all dyspepsia is related to H. pylori
25
and can be related to other gastrointestinal conditions such as celiac disease [92]. As
such, there are no classic signs of H. pylori infection in children and usually infection is
asymptomatic. Because of this children are rarely tested for infection despite the high
worldwide prevalence. The seemingly benign nature of H. pylori infection in childhood
has been questioned over the past decade as health researchers established the association
between H. pylori infection and iron deficiency.
Helicobacter pylori and iron deficiency
H. pylori infection is a known cause of iron deficiency and IDA in children and adults.
The biological mechanism for this is still unclear but evidence from case reports has
supported the cause-effect relationship between the two. Cross-sectional studies also tend
to support the association but at the population level, the association is typically
significant but weak. Below is an extensive review of studies examining the relationship
between H. pylori infection and iron deficiency and IDA.
There are several theories about the mechanism by which H. pylori causes iron
deficiency. These include bacterial mechanisms that sequester iron for growth, impair
iron absorption and/or and gastrointestinal bleeding [109, 110].
There is good evidence that H. pylori requires iron for its growth but there is limited
evidence to show that it can compete for iron in the human stomach. H. pylori bacteria
possess a lactoferrin binding protein which supports their growth in vitro [111, 112].
Lactoferrin, which is not normally present in the healthy adult stomach, was found in the
stomachs of patients and biopsy specimens with both mild and severe H. pylori
associated gastritis [111, 113-115]. Another study reported that less injected, labeled iron
than expected was incorporated into red blood cells and was not diverted to the
reticuloendothelial system as occurs in inflammation [116]. They theorized that iron was
diverted to the patients stomachs [116]. Despite the above findings, there has been no
evidence showing in vivo that H. pylori can sequester iron from within the body or
competes for it in the stomach, and as such, these mechanisms remain theories.
26
Another theory is that H. pylori alters the pH environment of the stomach which can
impair iron absorption [109]. H. pylori infection typically occurs in the corpus or fundus
of the stomach [92]. These regions of the stomach contain most of glandular tissue
responsible for hydrochloric acid (HCl) secretion which lowers stomach pH [117]. When
H. pylori infection occurs in these region, damage to glandular tissue and inflammation
results in decreased HCl output, increasing stomach pH [109]. The reduction of non-
heme iron requires a low acidity and thus H. pylori infection may reduce the
bioavailability of non-heme iron.
There is good evidence for the above theory. There has been some evidence of
glandular atrophy occurring in young children, suggesting that it is possible that acid
disturbances can occur, even in children who have not been infected as long as adults
[118]. Studies have shown that in adults and children, subjects with H. pylori infection
coupled with IDA, have increased stomach pH and reduced ascorbic acid concentrations
compared to subjects with infection but no IDA or those with just IDA and no infection
[109, 119, 120]. In addition, certain strains of H. pylori are known to be more aggressive
than others and these are associated with more severe mucosal damage in adults [110].
One recent study reported that among 52 school age children, those infected with more
severe strains had lower ascorbic acid concentrations in gastric juice than those with less
aggressive strains [121].
Finally, it has been suggested that gastrointestinal blood losses associated with H.
pylori induced gastritis could lead to iron deficiency [122]. It is known that bleeding
peptic ulcers can cause iron deficiency however, it usually takes years to develop this
condition and is unlikely to explain H. pylori associated iron deficiency in children [107].
However, inflammation of the gastric mucosa, which can occur in children, could result
in microscopic blood loss but currently little is known about the histological changes that
occur in the gastric mucosa in children with H. pylori infection [109].
There are various theories about how exactly H. pylori could induce iron deficiency.
The above studies provide support for these but are not definitive. The mechanism thus
27
remains unclear and as will be reviewed next, the strongest evidence for the relationship
between H. pylori and iron deficiency comes from case report studies.
Five articles, published between 1993 and 2003, reported 15 cases of children who had
IDA that could not be managed by conventional treatment, also known as refractory IDA
[116, 123-126]. In all cases, H. pylori was diagnosed and IDA resolved after eradication
of the infection and where follow-up was done months later, there was no indication of
IDA. Another study reported a case series of 28 adult premenopausal female patients who
presented with a long history of IDA and H. pylori infection [127]. Follow-up for
infection status and iron status occurred at 3, 6 and 12 months. At 6 month, 75% of the
women had recovered from IDA and 12 months 91.7% had recovered [127]. While serum
ferritin increased significantly from pre-treatment levels (6.2 ± 0.8 µg/L to 23.9 ± 6.7
µg/L), it remained below the adult cut-off values at 12 months [127]. From this report, it
is possible that iron status improved only enough to prevent anemia but storage iron
deficiency was still present at 12 months.
The above case reports reveal a cause-effect relationship between the bacteria and iron
deficiency. Evidence from cross-sectional studies has been mixed. In 2000, H. pylori
antibodies and IDA were measured in 375 Korean boys and girls aged 10 to 15 years
[128]. There were significantly more H. pylori positive subjects in the IDA group.
Similar results were found in another study with 660 Korean adolescents suggesting that
H. pylori infection is a risk factor for IDA [129]. However, neither study group assessed
the independent effect of infection over diet or potential sociodemographic confounders
so it is unclear as to whether H. pylori was independently associated with IDA.
In the United States from data for participants older than 2.99 years from NHANES
(1999-2000), H. pylori significantly explained differences in IDA status with an odds
ratio of 2.7 (95% CI: 1.5-4.8) when adjusted for age, sex, poverty, pregnancy and
gestational history [64]. The association remained significant when further adjusting for
race/ethnicity, vitamin C intake, some chronic illnesses and country of birth (OR = 2.6,
95% CI: 1.5-4.6) [64].
28
Among Inuit, the evidence is mixed. Among Alaskan native children, H. pylori
infection is independently associated with iron deficiency, but the association was modest
[59]. Prevalence ratios (PR) for iron deficiency and H. pylori were significant (PR = 1.6,
95% CI: 1.1–2.4) [59].1 After controlling for sex, village of residence and household size,
H. pylori explained a significant amount of the variation in iron deficiency status, but
only for children 9 or older (9 years: OR = 5.1, 95% CI: 1.1-23.0; 10-11 years: OR = 5.3,
95% CI: 1.5-19.0) [59]. While they did not control for household size, a similar study in
Alaska found that infection was significantly associated with iron deficiency but only in
those under 20 years of age [102]. In both of these studies, only iron deficiency, and not
IDA, was associated with H. pylori infection.
Overall in Alaska Natives there is a significant but modest association between H.
pylori and iron deficiency, but perhaps in people aged 9 to 20 years and not with more
severe forms of iron deficiency [59, 102]. Canadian Inuit are similar in social and cultural
practices to Alaska Natives and perhaps there exists a similar relationship between H.
pylori and iron deficiency in Nunavut.
In a northern Manitoba First Nations community, 57% of children were anemic but
there was no association between hemoglobin level and H. pylori status [101] . However,
the participants ranged in age from 6 weeks to 12 years and they did not examine age-
specific relationships as was done in Alaska. They also did not assess iron deficiency.
Among infants in two northern Cree communities and in one Kivalliq Inuit community,
cow’s milk consumption and not H. pylori infection was independently associated with
iron deficiency [51]. However, this age group was younger than in the Alaskan studies.
At the population level, age may be an important factor when examining this
relationship where younger age groups may not be affected [51, 59, 102]. Further,
although there is evidence of a significant association, it is typically weak and likely
other factors are also important in determining iron status [59, 64]. However, when H.
pylori emerged as a cause of iron deficiency, various eradication studies were conducted.
Overall, they provide mixed evidence on this issue.
1 % with ID and H. pylori / % with ID without H. pylori
29
Initial small eradication trials seemed to support the use H. pylori eradication therapy
in the management of IDA and iron deficiency. Although there is some debate about the
treatment of H. pylori in general, standard treatment in children seems to be 2 weeks of
triple antibiotic therapy [92, 107]. In Korea, a small double-blinded randomized control
trial was conducted with 25 boys and girls aged 10 to 17 years, all with H. pylori and
IDA [130]. Groups that received H. pylori treatment had higher hemoglobin than the
group that received only iron treatment. The group that received both iron and H. pylori
therapy showed the most prominent increase in hemoglobin. There were no significant
differences in changes in serum ferritin levels, serum iron and TIBC in any of the groups.
The same author conducted two other eradication trials, one among 11 girls aged 15 to 17
years and the other among 22 girls aged 15 to 17 [129, 131]. The results were similar to
the first and they also found significant increases in serum ferritin levels after eradication
of infection. While these three trials are promising, they were small and not generalizable
enough to make health care recommendations.
In another study, 160 children aged 6 to 16 with H. pylori infection were treated and
changes in various iron indices were observed [132]. They found that treating the H.
pylori infection significantly improved hemoglobin, MCV and serum ferritin in the
children who had IDA. In children with iron deficiency but not anemia, ferritin
concentration improved after eradication treatment. However, the lack of a control group
limits these findings.
To date, only two large population-level trials have been conducted [133, 134]. These
were among children in Alaska and in Bangladesh, both regions with high rates of H.
pylori infection as well as evidence of moderate iron deficiency and of H. pylori-
associated iron deficiency [59, 120, 135]. In Alaska, the H. pylori treatment trial involved
219 native children aged 7 to 11 in western Alaska. In Bangladesh the study involved 4
periurban communities with 200 children aged 2 to 5 years. In both studies, H. pylori
treatment provided no benefit over iron treatment alone.
Both of these studies are complicated by the fact that eradication therapy is not always
successful and re-infection in children is more common than in adults [136, 137]. For
30
example, in Alaska, the children in the H. pylori treatment group who were infection-free
throughout the entire study period had 24% less iron deficiency than compared to the
group receiving iron therapy alone, even though the relative risk was not significant. The
Alaskan study group suggests that longer follow-up is needed since perhaps epithelial
damage caused by the bacteria takes longer to heal and hence, it takes longer to resolve
iron deficiency [133]. But overall in these two studies, the effect of iron therapy alone
was similar to that of H. pylori plus iron therapy, suggesting that nutritional iron
deficiency may also be a causal factor in some children.
The evidence supporting the cause-effect relationship between H. pylori infection and
iron deficiency comes mostly from case-studies and some large cross-sectional studies,
including one from Alaska. In addition, given the likely high prevalence of H. pylori
infection among Canadian Inuit, this risk factor is important to address in studies of iron
deficiency.
2.3.4. Underlying risk factors for iron deficiency
The primary objectives of this study are to estimate the prevalence of iron deficiency and
IDA among Inuit preschoolers in Nunavut. Should prevalence rates be high, it is
important to investigate risk factors that could direct public health interventions. As
described above, dietary iron intake and H. pylori infection are two risk factors that could
reasonably affect the iron status of young Inuit children. In addition, certain underlying
socioeconomic risk factors for iron deficiency, such as food insecurity and household
crowding, are thought to be prevalent among Canadian Inuit.
Food security as defined by the United States Department of Agriculture (USDA)
means “access by all members at all times to enough food for an active health life” This
includes the “ready availability of nutritionally adequate and safe foods” and “assured
ability to acquire acceptable foods in socially acceptable ways” [138, 139]. Food
insecurity exists when there is “limited or uncertain availability of nutritionally adequate
and safe foods or limited or uncertain ability to acquire foods in socially acceptable
ways.” [138, 139] Food insecurity has been shown to increase risk of iron deficiency in
young children [140]. It is also an emerging concern in Nunavut and thought to be very
31
prevalent throughout the territory [68]. While territory-wide information is lacking, in
one Nunavut community, five out of six Inuit household were food insecure [69].
Household crowding has been shown to be common among Canadian Inuit. According
to the 2006 Aboriginal Peoples Census, 43% of Inuit children under the age 6 live in a
crowed home, compared to 7% of non-Aboriginal Canadian children [141]. In addition,
Alaskan native children were 1.4 times more likely to be iron deficient, but not iron
deficient anemic, when they lived in crowded homes [59].
32
Table 2-1. Institute of Medicine (2001) reported absolute requirements and Dietary Reference Intakes (DRIs) for iron in male and female infants, children and adults. Age group Absolute Requirement,
97.5th percentile (mg/day)
EAR a (mg/day)
RDA a (mg/day)
UL a (mg/day)
0 to 6 mos. - AI a: 0.27 40 7 to 12 mos. 1.07 6.9 11 40 1 – 3 years 1.23 – 1.36 3.0 7 40 4 – 8 years 1.45 – 2.01 4.1 10 40 Girls 9 – 13 years 1.44 5.7 8 40 14 – 18 years 2.7 7.9 15 45 Women 19 – 30 years 3.15 8.1 18 45 31 – 50 years 3.15 8.1 18 45 51 – 70 years 1.44 5 8 45 > 70 years 1.44 5 8 45 Boys 9 – 13 years 1.44 5.9 8 40 14 – 18 years 1.98 7.7 11 45 Men 19 – 30 years 1.44 6 8 45 31 – 50 years 1.44 6 8 45 51 – 70 years 1.44 6 8 45 > 70 years 1.44 6 8 45 Pregnancy 14 – 18 years ~1.2 - 5.6 23 27 45 19 – 30 years 1.2 - 5.6 22 27 45 31 – 50 years 1.2 - 5.6 22 27 45 Lactation 14 – 18 years 1.26 7 10 45 19 – 30 years 1.17 6.5 9 45 31 – 50 years 1.17 6.5 9 45 a Estimated Average Requirement (EAR), Recommended Dietary Allowance (RDA), Adequate Intake (AI), Tolerable Upper Level of Intake (UL)
33
Table 2-2. Summary of prevalence studies in anemia and iron deficiency for Inuit and northern First Nations children, and comparison groups.a Source Population n % Canada, non-Aboriginal Zlotkin 1996 [46]
Urban areas, 8.5 – 15.5 mos
428 ID: 33.9% (SF < 10 µg/L) IDA: 5.1% Anemia: 8% (Hb < 110 g/L)
Gray-Donald 1990 [63]
Montreal, Low-income 10 – 14 mos
218 IDA: 24.3%
1970-1972 NCNS [60]
NCNS 0 – 4 y
1249 535
IDE: 12% (TS < 16%) Anemia: 5% (Hb < 110 g/L)
Valberg 1976 [62]
NCNS sub-sample 0 – 4 y
87 ID: 30% (SF < 10 ng/mL) IDA: 2%
American, non-Aborignal Cardenas 2006 NHANES (1999-2000)
3 – 5 y 357 ID: 4.6% b
IDA: 0.5% Anemia: 1.5% (Hb < 112 g/L)
Inuit NCNS 1975 Kivalliq
0 – 4 y 29 35
IDE: 24% (TS < 16%) Anemia: 5% (Hb < 110 g/L)
Verdier 1987 [61]
High arctic Children and adults
678 IDE: 3-7% (TS < 5th %ile) Anemia: 11-26% (Hb < 5th %ile)
Young 1995 [56]
Kivalliq 9 mos – 17 y
440 Anemia: 12% (criteria not stated)
Young 1995 [56]
Kivalliq 9 mos – 2 y
NR Anemia: 27% (criteria not stated)
Willows 2000 [45]
Nunavik 12 mos
95 ID: 60% (SF < 2 SD below mean) IDA: 26.3% Anemic: 37.8% (Hb < 100 g/L)
Christofides 2005 [51]
Kivalliq 4 – 18 mos
50 ID: 36.9% (SF < 12µg/L) ID: 25.5% (sTfR > 8.5 mg/L) Anemic: 48% (Hb < 110g/L)
Bagget 2006 [59]
Alaska Native 7 – 11 y
686 ID: 38% (SF < 10 µg/L) IDA: 7.8% Anemia: 15.2%
Peterson 1996 [58]
Alaska Native 0 – 5 y
51 ID: 70% (SF < 12 µg/L) Anemia: 17% (1989 CDC cut-off)
a Hb – Hemoglobin; ID – Iron deficiency; IDA – Iron deficiency anemia; IDE – Iron deficiency erythrpoiesis; NCNS - Nutrition Canada National Survey; NHANES – National health and nutrition examination survey; NR – not reported; SF - serum ferritin; sTfR – serum transferrin receptor; TS – Transferrin saturation; b Iron deficiency when two of SF < 10 µg/L, TS < 12% or EP > 1.24 µmol/L
34
Table 2-3. Estimated iron content of some traditional Inuit foods and market foods. Per 100 g of food: Traditional foodsa: Scientific name Energy (kcal) Iron (mg) Bearded seal meat, boiled Erignathus barbatus 169 23.5 Bearded seal meat, raw Erignathus barbatus 121 20.0 Ringed seal liver, raw Pusa hispida 127 48.6 Ringed seal meat, boiled Pusa hispida 164 27.3 Ringed seal meat, raw Pusa hispida 127 19.2 Beluga meat, dried Delphinapterus leucas 356 57.0 Narwhal meat, dried Monodon monoceros 425 70.0 Walrus meat, aged Odebenus rosmarus 170 19.5 Walrus meat, boiled Odebenus rosmarus 191 26.0 Walrus meat, raw Odebenus rosmarus 117 17.8 Arctic char, dried Salvelinus alpinus 436 2.6 Arctic char, flesh boiled Salvelinus alpinus 158 0.5 Arctic char, flesh raw Salvelinus alpinus 105 0.3 Clams, meat boiled Mya spp. 65 3.4 Mussels, meat boiled Mytilus edulis 81 35.0 Duck Anas platyrhynchos 166 10.6 Ptarmigan meat, cooked Lagopus spp. 174 7.3 Canada Goose, flesh Branta canadensis 200 9.8 Caribou liver, raw Rangifer tarandus pearyi 124 40.2 Caribou meat, boiled Rangifer tarandus pearyi 213 7.0 Caribou meat, dried Rangifer tarandus pearyi 317 11.8 Caribou meat, raw Rangifer tarandus pearyi 127 4.9 Musk-ox Ovibos moschatus 10 4.5 Polar bear meat, boiled Ursus maritimus 208 6.7 Market Foodsb: Cereal 408 ~13 Chicken breast 156 0.5 Fish sticks 274 0.7 Tuna 116 1.5 Pork chops 261 1.0 Ribs 317 1.4 Bacon 568 1.6 Hotdog 242 2.3 Ground Beef 237 2.4 Stewing Beef 194 3.8
a Adapted from Traditional Food Composition Nutribase, Centre for Indigenous People’s Nutrition and Environment [142]. b Adapted from Nutrient Value of Some Common Foods [143].
35
Table 2-4. Summary of reported prevalence rates of Helicobacter pylori infection in northern or Arctic regions, and in comparison groups. Source Population Test Age n Prevalence Canadian Inuit and First Nations Christofides 2005 [51]
Northern Ontario First Nations and Kivalliq Inuit
IgG
4 – 18 mos 107 39%
Bernstein 1999 [84]
Northern Ontario James Bay Cree
IgG
20 – 50 y 306 95.1%
Sinha 2002 [101] Northern Manitoba First Nations
Stool 6 wk – 12 y 163 56.4%
McKeown 1999 [85]
Kivalliq Inuit IgG
15 y + 256 50.8%
Alaska Baggett 2006 [59]
Southwestern Alaska Native
UBT 7 – 11 y 688 86%
Parkinson 2000 [102]
Alaska Native IgG
0 – 4 y 260 32%
Greenland Koch 2005 [103] West Greenland Inuit IgG
0 – 4 y 100 6.1%
Koch 2005 [103] West Greenland Inuit IgG 0 – 87 y 685 41% Canada and United States Segal 2008 [100] Urban city Canadians,
with GI symptoms UBT 5 – 18 y 167 7.1%
Cardenas 2005 [64]
USA, NHANES (1999-2000)
IgG 3 – 5 y 357 5.5%
38
3 RATIONALE
Current information is not available on the prevalence of iron deficiency and IDA
among Inuit children aged 3 to 5 years in Nunavut. The most recent estimates, around
24% for tissue iron deficiency and 5% for anemia from all causes, are for both infants
and preschoolers and are from the 1972 NCNS [60]. Recent estimates for the prevalence
of iron deficiency and IDA among non-Aboriginal infants are around 33% and 5%
respectively [46]. Those for Inuit infants are higher at 36 to 60% and 26% respectively
[45, 51]. While rates among preschoolers are likely lower than those for infants, Inuit
children seem to be at higher risk for iron deficiency than non-Aboriginal Canadian
children. Given the detrimental health outcomes of IDA and possibly iron deficiency in
children such as impaired growth, cognitive development and immune defense, it is
important to determine prevalence rates of iron deficiency and IDA among preschool
aged Inuit children [15, 33].
Should the prevalence rates estimated from this study suggest that a health
intervention is needed, it will be important to provide some information around risk
factors for iron deficiency. Risk factors that most likely affect Inuit are related to the diet
and infection with H. pylori. Previous studies show that iron intake is likely adequate
among Inuit children [66, 74]. However, a nutrition transition in the Arctic is occurring
rapidly so current dietary information for this age group that can be matched with iron
status is needed. Infection with H. pylori is another important risk to assess since it has
been recently shown to cause iron deficiency and this pathogen is highly prevalent in
most Inuit populations [51, 59, 84, 85, 101]. In addition to diet and H. pylori, collecting
information on certain characteristics of the household may help to describe conditions
that increase children’s risk of iron deficiency. An understanding of the relationship of
these risk factors with iron deficiency and IDA among Inuit children, ages 3 to 5 may be
used to direct future health care planning in Nunavut.
39
3.1. OBJECTIVES
The objectives of the study “Iron deficiency and iron deficiency anemia among preschool
aged Inuit children living in Nunavut” are three-fold:
• To estimate the prevalence of iron deficiency, anemia and iron deficiency anemia
among Inuit children aged 3 to 5 years participating in the survey
• To describe the risk of inadequate iron intake among participating children
participating in the survey
• To describe the relationship of between iron status and various risk factors,
including exposure to H. pylori, food insecurity and household characteristics
among participating children
3.2. HYPOTHESES
It is hypothesized that Inuit children, ages 3 to 5 years, in Nunavut will have a higher
prevalence of iron deficiency than North American children overall. It is hypothesized
that dietary iron intake in this population will be adequate. It is also hypothesized that H.
pylori will be an independent predictor of iron deficiency and that food insecurity and
crowding in the home will be associated with increased risk of iron deficiency.
40
4 METHODS
4.1. PARTICIPATORY RESEARCH PROCESS
The Nunavut Inuit Child Health Survey (ICHS) was developed by a steering committee
of Inuit organizations, Canadian Universities and the Government of Nunavut. The
steering committee consisted of representatives from Nunavut Association of
Municipalities (NAM), Nunavut Tunngavik Incorportated (NTI), Government of
Nunavut Department of Health and Social Services (GN DHSS) and the University of
Toronto together with the Principal Investigator, Prof. Grace Egeland of McGill
University, Centre for Indigenous Peoples’ Nutrition and Environment (CINE). In
particular, the Department of Health and Social Services and Nunavut Tunngavik Inc
worked in developing the scope of the survey and in the revisions of the questionnaires.
Nunavut Association for Municipalities coordinated the translations. The steering
committee reviewed and revised the informed consent forms and played an active role
throughout the development of the research project. Further, discussions with other
organizations helped shape the child health survey.
Research agreements were sent to each Hamlet, requesting their approval and
involvement in “Qanuippitali?” Professor Grace Egeland and “Qanuippitali?” planning
staff are based out of CINE, McGill University. “Qanuippitali?” followed closely the
framework presented in Indigenous Peoples and Participatory Health Research, as per
CINE’s guiding principles [1].
4.2. SAMPLE SIZE CALCULATION
The sample size for ICHS was determined based upon the primary objective of
determining the prevalence of iron deficiency anemia (plus or minus 5%) among the 3 to
5 years olds. 2005 population estimates for Nunavut were obtained from Statistics
Canada and the Nunavut Bureau of Statistics and increased by 2% per year until 2007 to
account for population growth (Table 4-1). The estimated population size for children
aged 0 to 4 years was 3609. The specific age grouping of 3 to 5 years was not available.
In addition this estimate included Inuit and non-Inuit children living in Nunavut. The 3 to
41
5 year old Inuit population size in Nunavut was estimated to be 3000 children for sample
size calculations. The sample size was calculated to allow for detection of 10% iron
deficiency anemia (plus or minus 5%). This prevalence estimate is consistent iron
deficiency anemia studies in Alaskan Inuit children as well as some smaller studies with
Canadian Inuit infants. At a 90% confidence, the required sample size for the entire
territory of Nunavut was 94 children using EpiInfo Stat Calc Version 6. In order to allow
for detection of less common health indicators and to enable multivariable modelling on
the determinants of iron deficiency anemia, the desired sample size was tripled to 300.
Also, field survey staff members were instructed to over-sample to account for a
proportion of children or care givers refusing a venous blood draw.
Sixteen of the 25 communities in Nunavut were selected to participate in the ICHS.
Given the high costs of travel, communities with a very small population of 3 to 5 year
olds (estimates of less than 30) and/or with excessive travel costs were excluded from the
child health survey: (i.e., Resolute Bay, Grise Fiord and Qikitarjuaq). Communities were
selected based upon region, population size (small, medium and large size communities),
latitude (from South to North), and then finally logistical feasibility due to flight routes
and financial constraints. We used the estimated population sizes of 3 to 5 year olds in
each community to determine what proportion of children aged 3 to 5 in each community
should be recruited to allow us to reach our sampling goal. As shown it was estimated
that a sample of 20% of 3 to 5 year olds in each community would allow for an overall
sample size of approximately 450, which was consistent with our sampling goal of 300
children plus over-sample for refusal of venous blood draw (Table 4-1).
4.3. STAFFING AND TIMEFRAME FOR DATA COLLECTION
The 2007 research team consisted of a bilingual Inuk nurse who conducted all
venipuncture and the majority of the clinical assessments, a bilingual Inuk interviewer
who conducted the majority of the interviews and two research assistants from CINE,
McGill University who were responsible for training, logistical arrangements,
recruitment, interviewing, assisting the nurse, file management and blood sample
42
preparation. The 2008 research team was similar except that the nurse was a non-Inuk
Northern nurse who had previous experience working in the Nunavut.
The ICHS took place in late summer and fall in 2007 and 2008 (Table 4-2). Data
collection began in Sanikiluaq in early August 2007. Sanikiluaq was visited early because
research assistants were already in the community to conduct the adult health survey. The
remainder of the 2007 child survey took place from September 24th, 2007 – November
23rd, 2007 and 11 communities were visited. The 2008 child survey included 4
communities in the Kitikmeot region from August 20, 2008 – September 9, 2008.
4.4. RECRUITMENT
Inuit children, ages 3 to 5, were randomly selected to participate in survey. In order to
reach our total sample size and to make efficient use of staff, an approximate goal was
20% of the sample of children aged 3 to 5 years in selected communities were sampled.
Children were recruited through a list of homes with children ages 3 to 5 that participated
in the ship-based adult health survey and through a list of names of all children ages 3 to
5 that was provided by the local health centers. A randomized list of children was created
from the health centre list using a random number table. Caregivers were contacted in the
order that they appeared on the randomized list.
Usually, caregivers were first contacted by telephone. If no phone number was
available, attempts were made to visit the home. If no one was home, pamphlets were left
at the home with the research team’s contact information. On occasion we asked the
community radio to have the selected participant call the research team or we would ask
the health center workers for their help in finding people. Three attempts were made to
contact households. Ideally, each of these attempts employed a different method of
communication. However, we had limited time in each community and often only
telephone calls were possible. Refusals, no shows and reasons for refusal were recorded.
Once a caregiver was reached they were asked to participate with their child in the
health survey. They were asked to come to the health centre (or other specified location)
to go through the informed consent process. If they gave written informed consent, an
43
interview and clinic appointment was completed. As much as possible, appointments
were scheduled in the morning to avoid the effects of diurnal variations in biomarkers.
4.5. ETHICS APPROVAL
Certification of Ethical Acceptability for Research Involving Human Subjects for the
“Qanuippitali?” Inuit Health Survey was obtained from the McGill Faculty of Medicine
Institutional Review Board in March 2007 (Project # A03-E08-07B). An amendment was
made to include venipuncture as part of the Child Inuit Health Survey protocol. This
amendment was approved in June 2007.
A Scientific Research License was obtained from the Nunavummi Qaujisaqtulirijikkut
(Nunavut Research Institute) from April 01, 2007 to December 31, 2009 (Licence #
0500607N-M).The Nunavut Research License was successfully renewed after each year
of data collection. A DVD was made that followed the McGill Informed Consent form
word-for-word and was made available in the appropriate dialects for the 3 Nunavut
regions included in surveyed.
4.6. INTERVIEWS
Interviews were conducted with the person who brought the children to their
appointment. The recruiter asked that the person who knew the most about the child
accompany the child to the appointment. We recorded information about the respondent’s
relationship to the child for quality control purposes and most often, the child’s primary
caregiver brought them to the appointment. After giving written informed consent, the
interviewer proceeded with the questionnaires. These are described below in more detail
as they relate to this study. When the interview was complete, the child would see the
nurse with the caregiver to complete the clinical assessments. Typically interviews were
completed prior to the clinical assessment unless time constraints required otherwise.
4.6.1. Interview training
All child health survey research team members were trained on interviewing skills and
dietary interviewing. Interviewing consisted of reading through each of the questions to
44
clarify the meaning of each if it was not clear. Interviewers were instructed to read
questions as worded in the questionnaire and to offer clarification only when requested.
Interviewers were instructed to use an objective tone when interviewing and not to ask
leading questions. No specific instructions were given as to the order in which to
administer each questionnaire however, the home-based questionnaire, ID chart and food
frequency questionnaire were a priority when interview time was limited. Typically, the
home-based questionnaire and ID chart were administered first and dietary questionnaires
were administered towards the end of the interview, with the 24-hour dietary recall being
filled before the food frequency questionnaire.
Interviewers were trained to use a five stage, multiple pass technique for collecting 24-
hour dietary recall information. Interviewers were trained to ask caregivers to give a list
of everything that their child ate during the day, from midnight-to-midnight, before the
interview. They were then asked to go back to collect more detailed information about
the food and drink listed, such as brand name, flavour or method of cooking for example.
They were they instructed to review the list again and collect portion size information
using 3D food models. The final stage was to review the information collected and probe
for any missing items such as snacks or water for example.
4.6.2. Inuktitut translations
The written consent form, the DVD consent form and the six questionnaires were
translated into three Inuktitut dialects: Nattilik, Inuinnaqtun and Baffin. Translations were
conducted by professional Inuit translators. Baffin Inuktitut translations were tested
during a small pilot study in Iqaluit, Nunavut and minor corrections were made to the
questionnaires. Nattilik and Inuinnaqtun questionnaires were translated once. Back-
translations were not done. Nattilik Inuktitut translations were used in Kugaaruk.
Inuinnaqtun translations were used in Cambridge Bay and Kugluktuk. Baffin Inuktitut
translations were used in the remaining thirteen communities, which were part of either
the Baffin or Kivalliq regions of Nunavut. Although some of these communities spoke
mainly the Kivalliq dialect of Inuktitut (or the Nunavik dialect as was the case with
45
Sanikiluaq), an interviewer who spoke the appropriate dialect was available for any
needed translations when these communities were surveyed.
4.6.3. Written informed consent
Written informed consent was obtained from the child’s caregiver prior to any
participation in the study. A person was considered a child’s caregiver if they were the
person primarily responsible for the child at the time of the study. Caregivers had the
option of reading the consent form, having it read to them, watching a DVD information
guide or all three. All options were available in English and Inuktitut. The DVD guide
was a word-for-word reading of the consent form, accompanied by photographs and
video-clips relevant to the study. Caregivers were asked to complete and sign two copies
of the consent form. They were given one copy and the second was retained.
4.6.4. Study numbers and confidentiality
Once caregivers had watched the supplementary information DVD and/or read and
completed the written informed consent form, the participating child was given two
confidential study numbers, one for the individual and one linking them to their
household. A list was created with the child’s first and last names, age, sex, box number,
house number, community and study number. Once the list was completed and verified,
identifiers were removed from the child’s file and placed in a sealed envelope. These
were hand-carried with project staff. Files without identifiers were periodically shipped to
McGill University through Canada Post. Upon return to Montreal, files were placed in a
locked room at McGill University. The confidential list and identifiers were placed in a
locked safe.
4.6.5. Participant compensation
Each child was given a Beanie Baby toy regardless of whether or not they completed the
entire child survey. Caregivers were given $15 gift-cards to either the Northern Store or
the Co-Op regardless of whether or not they completed the entire survey.
46
4.6.6. Demographic information and household characteristics
Interviewers asked questions about age, sex and relationships of everyone in the child’s
household. They also conducted questionnaires for characteristics of the home including
the USDA 18-item Household Food Security Survey Module [144]. Indian and Northern
Affairs Canada (INAC) modified the standard USDA module based on cognitive testing
with Inuit interviewers to improve acceptability among Inuit. For example, response
options such as “always true”, “sometimes true” and “never true” were replaced with
“often”, “sometimes” and “never” to avoid creating a situation where the respondent felt
that the truthfulness of their responses was being questioned [69]. A brief questionnaire
about the child’s current supplement use was also administered.
4.6.7. 24-hour dietary recall
One 24-hour dietary recall was conducted for each child participant using a five stage,
multiple pass technique described above. Food model kits were used to estimate portion
sizes. Some caregivers knew the volumes of liquid of food consumed and this
information was recorded. Often caregivers were not with their children for the entire 24-
hours. If this occurred, this was recorded along with any known information on what the
child ate was recorded. If possible, interviewers or the caregiver telephoned the person
that the child was with to at least record what the child ate. Depending on the number of
days spent in the community, all caregivers from the first or second day of appointments
were asked to return for a 20-minute appointment to complete a second 24-hour dietary
recall on a nonconsecutive day. The target number of repeat recalls was 20% of the total
sample of participating children.
4.6.8. Food frequency questionnaire
Each caregiver was asked to complete a qualitative food frequency questionnaire (FFQ)
for their child. The FFQ was designed was capture past month information about
common country foods that are available in the three regions of Nunavut. It also included
some market foods sources of iron such as beef, pork, fish, poultry and breakfast cereals.
Due to the difficulty of quantifying children’s “usual” portion sizes and to time
47
constraints, the child FFQ was not quantified. However, caregivers were asked about how
often the child ate the foods in the past month.
4.6.9. Quality control for interview component
For the 24-hour recall and the FFQ, a quality control tool was used (Appendix A). Prior
to leaving each community, each 24-hour recall and FFQ was reviewed by the research
team member with the most experience with dietary questionnaires. This person reviewed
the 24-hour recall to ensure that appropriate level of detail was obtained and that the
portion sizes and servings were being recorded correctly. If corrections were needed, they
made note of them in the quality control tool and reviewed them with the interviewer in
attempts to make corrections.
A similar quality control tool was used for the FFQ. The quality control tool also
served as a useful training tool so interviewers could improve upon their mistakes early
on in the project. These records were placed in the child participant’s file upon
completion. The other questionnaires were reviewed early on in the fieldwork to ensure
that the interviewers were not making any major errors.
No measures of inter-interviewer agreement were taken to assess consistency between
interviewers. All data were recorded in ballpoint pen on the questionnaires. All study
numbers were recorded on the front cover of the questionnaire. Questionnaires were
placed in the child’s file. A quality control checklist was completed to ensure that all
appropriate documents were in the file.
4.7. CLINICAL DATA COLLECTION
Clinical protocols are shown in Appendix B. If a clinical measure was not completed,
coded reasons for incompletion were recorded. The caregiver was always present for the
child’s clinical assessment and often along with the interviewer who would assist the
nurse. It is worth noting that parents and children seemed comfortable with the research
nurses who were familiar with working in Nunavut’s communities. The research team
created a positive and comfortable experience for both the child and the caregiver.
48
4.7.1. Anthropometry
Height was measured to the nearest 0.1 cm using a portable stadiometer (Road Rod 214
Portable Stadiometer, Seca, Maryland). Weight was measured once per child to the
nearest 0.1 kg using an electronic scale. Unless specified on the clinical sheet, shoes were
removed for both measurements. Results were recorded on the child’s clinical sheet and
the results were returned to the caregiver at the appointment. BMI-for-age, height-for-age
and weight-for-age percentiles and z-scores were calculated using EpiInfo Nutrition
Version 6 and the 2000 CDC reference growth curves [145].
4.7.2. Blood sample collection
Venipuncture
A certified nurse conducted venipuncture. Caregivers were asked again in the clinic if
they wanted venipuncture for their child. They were informed that if they opted for the
finger prick instead, that only the hemoglobin results could be given to them and not the
other indices measured in the blood. The nurse performed venipuncture using 23G¾
butterfly Vacutainer® brand blood collection sets (Becton Dickinson and Company,
Franklin Lakes, New Jersey). 3ml of whole blood was collected in 4.0 mL Vacutainer®
blood collection tubes coated with 68 USP units of sodium heparin (Becton Dickinson
and Company, Franklin Lakes, New Jersey). Venipunture was performed in the median
antecubital vein from the anterior forearm. If venipuncture from the forearm was not
possible or unlikely to work, as was often the case with the 3-year old children, the nurse
performed venipuncture from the dorsal hand veins. The vacutainer tube was inverted
gently 10 times. One drop of whole blood was dispensed onto Parafilm (Pechiney,
Chicago, Illinois) using a Diff-Safe® blood dispenser (Alpha Scientific Corporation,
Southeastern, PA) for hemoglobin measurement as discussed below. The tube was placed
in a fridge or on a blue medical pad placed over ice until processing within 6 hours. It
was noted on the child’s clinical sheet that venipuncture was used to collect blood.
The nurse encouraged caregivers to hold the children in their lap and place their arms
around their children’s arms for safety purposes. The assisting interviewer and the
49
caregiver tried to distract the child’s attention from the needle. When children were
unaware of what was happening, they rarely cried. With small-sized butterfly needles,
venipuncture feels like a small pinch and takes about 5 to 10 seconds to collect 3ml of
blood if the child is well hydrated. It should be noted that it is a privilege to be allowed to
collect blood for research purposes. As such, we tried as much as possible to make blood
collection quick and comfortable for the children, including giving the children “fun”
band-aids and allowing them to choose a toy to keep immediately after venipuncture.
If venipuncture was not possible because the nurse could not easily find a vein or the
child or caregiver was unwilling, it was explained that a finger prick could be performed
to test for hemoglobin only. Finger pricks were performed using OneTouch® UltraSoftTM
Sterile Lancets (LifeScan, Inc., Milpitas, California). The finger prick protocol used was
difficult with children. The capillary blood sample is more likely to contain extracellular
fluid that can dilute the samples. Hemoglobin results using HemoCueTM may be
underestimates of the child’s actual hemoglobin and this should be considered when
calculating statistics of anemia. If a finger prick was used to collect capillary blood, this
was recorded on the clinical sheet.
4.7.3. HemoCue™
Dispensed venous blood drops or blood drops from finger prick were analyzed for
hemoglobin concentration using the cyanmethemoglobin method with HemoCueTM 201+
portable photometer (HemoCue, Inc., Lake Forest, California). Either the nurse or the
interviewer assisting the nurse completed the hemoglobin measurement. Results were
recorded on the clinical sheet.
The photometer itself was tested every morning of the clinic for quality control
purposes. High, medium and low control samples were tested and results were compared
with expected results. Results were also recorded on a log sheet and monitored to ensure
consistency. The machine was also cleaned according to the manufacturers instructions
every two weeks or when needed. Cleanings were noted in the log sheet.
50
4.8. PLASMA SAMPLE PREPARATION
Sample number, time of preparation and how the sample was kept cold was recorded
prior to beginning plasma preparation (Appendix B). The vacutainer was inverted gently
10 times. The cap was removed and whole blood was dispensed using a wide-tipped
disposable transfer pipette (UltidentBRAND) into two or three 1.5 ml centrifuge
microtubes depending on the volume of blood collected. Blood was dispensed so that
tubes were balanced. Tubes were labeled and spun for 20 minutes at 2000xg in a
minicentrifuge (Mandel Scientific Company Inc., Guelph, Ontario). The vacutainer tubes
contained heparin, which is a blood anticoagulant.
Using a fine-tipped disposable transfer pipette (UltidentBRAND), plasma was slowly
removed and dispensed into a 2 ml microtube. The 2 ml microtube was labeled and
placed on a blue medical pad over ice until divided into aliquots for freezing. Hemolysis
or incomplete white blood cell removal were noted. The plasma was aliquoted into pre-
labeled 2 mL cryovial tubes according to the protocol using 1000 µL and 200 µl pipetors
(Biohit Inc., Neptune, New Jersey). A cryovial cap was tightly placed on the tube.
Sometimes less than 3 ml of blood was collected and not all aliquots of plasma were
obtained. As such, a record of all aliquots was made. Cryovial tubes were placed in
cardboard cryovial storage boxes. Elastic bands were placed around the box and they
were placed in the coldest freezer available in each community, which was usually minus
12ºC to minus 20ºC. Freezer temperature was recorded twice daily to ensure plasma
samples would remain frozen.
When traveling from community to community, cryovial boxes were kept in coolers
packed with icepacks. They were marked as “Keep frozen”. Because luggage is
sometimes shipped later when traveling on small airplanes, airport staff were asked to
give first priority to the coolers in terms of deciding which luggage would go on our
airplane. When returning from Nunavut to Montreal, coolers were sent with checked
baggage and marked as “Keep frozen”. Coolers were stored in freezers in any overnight
stops. Cryovial boxes were placed in a locked minus 80ºC freezer upon return to CINE,
McGill.
51
4.9. LABORATORY ANALYSES
4.9.1. Measurement of C-reactive protein
CRP was measured in the 2007 plasma samples using CRP (Human) Enzyme Linked
Immunosorbance Assay (ELISA) (2007: Pheonix Pharmaceuticals, Inc., Burlingame,
California). In 2008, plasma samples were sent out for CRP analyses due to time and
labour constraints. They were sent to a clinical diagnostic laboratory at the Montreal
General Hospital.
The 2007 plasma samples were analyzed as follows. Frozen plasma samples were
thawed over ice for 1 hour. 10 µL of plasma sample was diluted in 1490 µL of 1x assay
buffer concentrate to provide a 1:150 dilution of sample. A standard curve was created by
creating a serial dilution of the standards provided. 100 µL of standards, samples and a
control were added in duplicate to plated wells. Two wells were left blank so as to have a
zero concentration value on the standard curve. The control and one of the samples were
plated in triplicate to allow for calculation of the coefficient of variation (CV). The plate
was sealed and incubated on the shaker at medium speed for 2 hours at room temperature
(18°C - 27°C). Wells were washed with 300 µL assay buffer per well. The plate was
washed four times. 100 µL of anti-human CRP-HRP Detection Antibody was added to
each well except for the blank wells. The plate was sealed and incubated for 2 hours at
room temperature (18°C - 27°C) on the shaker at medium speed. Wells were washed
again four times with 300µL assay buffer per well. In a dark room, 100 µL of
tetramethylbenzidine substrate solution was added to each well. The plate was sealed and
incubated for 25 minutes at room temperature on a shaker at medium speed in the dark.
100 µL of 2N HCL stop solution was added to each well. The plate was read at 450 nm
using a spectrophotomer. CRP concentrations were quantified from optical density (OD)
results using GraphPad Prism 4.
The CVs for the plasma sample and control plated in triplicate ranged from 0.99% to
10.8%, except for one control CV that was high at 42%. All samples with a CV less than
10% were repeated. Outliers were repeated using a different dilution. Low outliers were
52
repeated using a dilution of 1:25 to 1:50. High outliers were repeated using a dilution of
1:750 to 1:1000. We were unable to determine an exact value for some samples because
the concentration of CRP in the plasma was either too high or too low and the second or
third attempt at diluting still produced at outlier result. These samples were noted and the
low concentration samples were assumed to be below the CRP cut-off. Similarly, the
high concentration samples were assumed to be above the CRP cut-off.
The 2008 plasma samples were measured for CRP using a SYNCHRON®
Autoanalyzer (Coulter Beckman, USA) and a high-sensitivity CRP (hsCRP) assay at
the Montréal General Hospital, Montréal, Québec. The autoanalyzer was suitable for use
with human serum and plasma. According to the manufacturer, plasma samples collected
with sodium heparin anticoagulant had CRP concentrations that were correlated well with
serum samples (r = 0.997). The principals of the hsCRP assay are as follows. The
autoanalyzer proportions one part plasma sample to twenty-six parts hsCRP reagent. The
reagent contains 17.3 mL CRP antibody (particle bound goat and mouse anti-CRP
antibody, 47.8 mL reagent buffer, <0.1% (w/w) sodium azide and <0.125% (w/v) bovine
serum albumin). 300 µL of plasma sample was used in the analyses. CRP in the human
plasma sample mixes in the autoanalyzer with particle bound goat and mouse anti-CRP
antibody. The SYNCHRON® system monitors the change in absorbance at 940 nm. The
absorbance is proportional to the CRP concentration in the sample. CRP concentration is
then calculated from a pre-determined calibration curve.
4.9.2. Measurement of Helicobacter pylori exposure status
To measure exposure to H. pylori, plasma samples were tested for IgG antibodies against
the pathogen. The presence of anti-H. pylori antibodies indicates exposure to the
pathogen but not necessarily current infection. Current infection is assessed using gastric
endoscopy, a urea breath test or a stool antigen test, all of which were not used due to
logistical constraints in remote field settings.
Plasma samples were shipped in coolers from CINE to the laboratory of Dr. Brian
Ward at McGill University, Centre for the Study of Host Resistance, Montreal General
Hospital, where they were analyzed for H. pylori exposure. A qualitative ELISA (Pylori
53
Detect IgG, Calbiotech, Spring Valley, California) was used to analyze plasma samples
for the presence of anti-H. pylori IgG antibodies. ELISA kits were brought to room
temperature (18°C to 27°C) prior to use. Plasma samples were thawed and diluted using
10 µL of plasma and 1 mL of diluent/wash solution provided by the ELISA kit
manufacturer. 100 µL of each sample was pipetted into microwells coated with H. pylori
antigen. Samples were tested in singlet. One each of a blank, calibrator, positive control
and negative control well was created on each microplate. Microplates were incubated for
20 minutes at room temperature. Wells were washed three times with diluent/wash
solution. 100 µL of goat anti human IgG enzyme conjugate was added to each well
allowed to incubate at room temperature for 30 minutes. Wells were washed again three
times using diluent/wash solution. 100 µL TMB substrate was added to each well and
then after a 20 minute incubation at room temperature, 100 µL of stop solution was added
to each well. Absorbance was read at 450 nm using a spectrophotometer within 15
minutes of the addition of stop solution and optical density obtained for each sample.
To interpret results, the OD of the plasma sample was divided by the OD of the
calibrator. If the result, also called the ELISA value, was greater than or equal to 1, then
the sample was positive for H. pylori exposure. ELISA values less than 0.89 was negative
for H. pylori exposure. Samples between 0.89 and 0.99 were equivocal and were retested
once. If upon retest samples were still equivocal, results were said to be indeterminate.
No problems with blanks, positive controls or negative controls were reported. The
reported sensitivity of the Pylori Detect IgG ELISA was 98.3% and specificity was
94.4% when compared to endoscopy. The cut-off values for exposure, non-exposure or
equivocal results were determined using sera from confirmed infected and non-infected
human patients.
4.9.3. Measurement of ferritin
Ferritin was measured from plasma samples using the Liason® autoanalyzer in the
laboratory of Dr. Hope Weiler in the School of Dietetics and Human Nutrition, McGill
University. Frozen plasma samples were thawed at room temperature (18°C - 27°C) and
at least 200 µL was pipetted into glass test tubes. All samples were spun at 2000xg for 5
54
minutes at 4ºC prior to loading onto the Liason®. Centrifugation of samples ensured that
any clots present in the sample were spun down, lessening the chance of clogging the
Liason® pipettor needles. This was especially important because the samples were
plasma and not serum, and as such, contained clotting factors. The presence of clotting
factors in plasma may increase the production of clots in the sample.
Racks were loaded into the Liason®. Study numbers were entered and the appropriate
tests were ordered for each sample. Ferritin concentrations were measured using a
Liason® Ferritin integral (REF 313551, DiaSorin, Italy). The ferritin reagent integral was
gently shaken horizontally before removing seals. Magnetic particles were re-suspended
by turning the thumb wheel at the bottom of the container back and forth until the
suspension turned brown. The integral was placed in the Liason® reagent area and was
left to stand for 30 minutes prior to using. A calibrator within the integral allows the
Liason® to re-calibrate the standard curve for each use. High, low and normal ferritin
controls were tested and were within expected range. The Liason® measures ferritin by
adding sample to a solution containing magnetic particles coated with specified mouse
monoclonal antibodies. A second monoclonal antibody conjugates to any ferritin present
in the sample and is linked to an isoluminal derivative, which allows for quantitative
measurement of the sample. The solution is incubated for 10 minutes and is then washed
with Liason® Wash/System Liquid (REF 319100). Starter reagents from the Liason®
Starter Kit (REF 319102) are added to the solution and induce a flash chemiluminescence
reaction which is measurable by a photomultiplier within the autoanalyzer. Results are
produced in relative light units and converted to ng/mL. The Liason® measures ferritin
concentrations between 0.5 and 3000 ng/mL.
4.10. DATA MANAGEMENT
Food frequency information was entered using EpiInfo Version 6 and data was double
verified. Twenty four-hour dietary recall information was entered using CANDAT.
Nutrient composition of foods was determined using the Canadian Nutrient File.
CANDAT was updated for various missing items using USDA nutrient composition data.
All 24-hour recalls were double verified. When information was missing from 24-hour
55
recalls, these were considered invalid and excluded from analyses. For example, when a
caregiver reported that the child ate meals at a relative’s home, but did not know what
was consumed, this recall was excluded. Unreasonable intakes were adjusted.
In addition, some assumptions were made when entering the 24-hour recall data.
Firstly, when caregivers reported that their child ate snacks or meals at daycare and did
not know what the child had, a default meal or snack was entered. Default snacks/meals
were determined using information from 24-hour recalls where this information was
provided in detail. The following defaults were entered:
• Daycare afternoon snack, one-fifth of: Yogurt (fruit bottom 2-4%, 100 g), water
(250 mL), raw apple (0.33 fruit), raw orange (0.33 fruit), raw banana (0.33 fruit),
raw celery (one 10 cm strip), raw carrot (one medium strip), raw broccoli (1
stalk), raw cucumber (0.05 of one 22 cm cucumber), white bread (1 slice), cheese
slice (21.0 grams), bologna (1 slice 0.3 cm thick), butter (1 pat), jam, (15 mL),
Nutrigrain Bar (37.0 grams), two muffins
• Daycare morning snack, one-sixth of: hard boiled egg (0.75 large egg), scrambled
egg (0.75 large egg), Shreddies cereal (250 mL), Cheerios cereal (250 mL), Rice
Krispies cereal (250 mL), 1% milk (250 mL), 2% milk (250 mL), apple juice (2.5
glasses, 125 mL each), orange juice (2.5 glasses, 125 mL each), pancake (10 cm),
raw apple (0.5 fruit)
• Daycare lunch, one-half of: bagel (7.6 cm), one english muffin, banana (0.25
fruit), 1% milk (250 mL)
The remaining questionnaire and clinical information was entered into a Microsoft
Access Database designed for the Inuit Child Health Survey using Microsoft Access
2003. Data was entered into the database exactly as it was recorded in the questionnaire
according to a standard protocol. Then, data was generated and checked for data entry
errors.
56
4.11. STATISTICAL ANALYSES
Prevalence rates of anemia, IDA and iron deficiency were estimated as the proportion of
participating children presenting with the condition. Agresti-Coull 95% CIs were
calculated for each of the prevalence rates. Prevalence rates and 95% CIs were also
determined for each of the binomial risk factors.
Age specific WHO 2001 cut-off values for iron deficiency and anemia were used
(Table 4-3). Ferritin less than 12 µg/L was used to define iron deficiency. Hemoglobin
less than 110 g/L in 3 to 4 year olds, and less than 115 g/L in 5 year olds, was used to
define anemia. IDA was defined as the presence of low ferritin coupled with low
hemoglobin. A 10 µg/L cut-off value for ferritin in children has been used in similar
studies. We also performed statistical analyses using this cut-off. Further, the CRP cut-off
for acute inflammation is unclear in children. Some studies have used 8 or 10 ng/mL [51,
52]. Other studies suggest that 2 to 3 ng/mL are more appropriate [50, 53]. In young
children, baseline CRP levels should be almost zero and any elevation in CRP could be
indicative of acute inflammation occurring in the days leading up to sampling [50]. CRP
levels may be slightly elevated as they return to normal after inflammation, but ferritin
can still be elevated [50]. We performed statistical analyses using both 8 ng/mL and 3
ng/mL cut-off levels. Finally, because we used two different blood sampling methods,
venous puncture and finger prick, we compared the hemoglobin concentration within
each type of sample to test for differences.
Usual iron intake from 24-hour recall was estimated from observed intake using
Software for Intake Distribution Estimation (SIDE) developed by Iowa State University.
SAS version 9.1 was used to run SIDE software. Within-person variability was estimated
using information from the 19.8% sub-sample of repeat recalls. The percentage of
children below the age-appropriate EAR for iron was determined.
The use of a qualitative FFQ data in examining relationships with health outcomes is
still an area of exploration in nutrition research. One approach is to determine nutrient
intake from the FFQ by assuming an average portion size, often determined from 24-hour
dietary recalls previously administered in the study population [146, 147]. Another
57
approach was to group people into quantiles of frequency of consumption. A scoring
system was created using a combination of NHANES (1971-1975) 24-hour recall dietary
data and FFQ data [148]. Subjects in the highest quartile of calcium intake from a 24-
hour recall and highest quartile of calcium containing foods from the FFQ were grouped
into one category. Similarly, people in both of the lowest quartiles were grouped into one
category. Everyone else was grouped in an “All others” category. However, because it is
difficult to be sure in this study population that portion sizes are similar for children, the
FFQ was only used to provide descriptions of commonly consumed foods.
The outcome variables of interest were IDA and iron deficiency. Risk factor variables,
H. pylori exposure, household crowding, food insecurity, having a younger sibling and
iron intake, as well as age, sex and region are detailed in Table 4-3. Bivariate analyses of
outcome and risk factors as well as region, age and sex were performed using Chi-
squared test and Fisher’s exact test if there were less than 10 children in a group. Relative
Risks and 95% confidence intervals were calculated for each of the exposure variables
when p < 0.05. Chi-squared tests were used to examine intercorrelation of independent
variables. Multivariate analyses were performed using multiple-logistic regression.
Dietary adequacy analyses were determined using SIDE in SAS version 9.1. All other
analyses were performed using Stata 10 (Stata Corp, Texas).
58
Table 4-1. Nunavut communities, location and population sizes.
Community Pop. size -all ages
Pop. size - 0 to 4 y
% Inuit
Estimated pop. size - 3 to 5 y
20% sample - 3 to 5 y
Latitude Longitude
Kivalliq
Arviat* 2319 345 0.94 290 58 61° 6' N 94° 4' W
Baker Lake* 1683 175 0.93 147 29 64°18' N 96° 5' W
Chesterfield Inlet* 366 48 0.93 40 8 63° 21' N 90° 43' W
Coral Harbour* 780 105 0.97 88 18 64° 11' N 83° 21' W
Rankin Inlet* 2376 277 0.77 233 47 62° 49' N 92° 7' W
Repulse Bay 686 107 0.97 90 66° 31' N 86° 13' W
Sanikiluaq*a 742 92 0.95 77 15 56° 32' N 79° 15' W
Whale Cove* 316 42 0.95 35 7 62° 14' N 92° 36' W
Baffin
Arctic Bay 662 68 0.95 57 72° 59' N 85° 0' W
Cape Dorset 1193 144 0.93 121 64° 13' N 76° 31' W
Clyde River* 868 133 0.96 112 22 70° 29' N 68° 31' W
Grise Fiord 180 30 0.91 25 76° 25' N 82° 54' W
Hall Beach 678 104 0.96 87 68° 46' N 81° 14' W
Igloolik* 1404 205 0.95 172 34 69° 22' N 81° 48' W
Iqaluit* 6304 560 0.57 470 94 63° 45' N 68° 33' W
Kimmirut* 470 60 0.94 50 10 62° 51' N 69° 52' W
Pangnirtung* 1324 157 0.95 132 26 66° 7' N 65° 42' W
Pond Inlet* 1298 187 0.94 157 31 72° 40' N 77° 58' W
Qikitarjuaq 552 69 0.95 58 67° 33' N 64° 1' W
Resolute Bay 233 31 0.79 26 74° 43' N 94° 59' W
Kitikmeot
Cambridge Bay* 1387 135 0.79 113 23 69° 6' N 105° 8' W
Gjoa Haven 1116 147 0.95 123 68° 38' N 95° 51' W
Kugaaruk* 770 129 0.95 108 22 68° 32' N 89° 48' W
Kugluktuk* 1324 139 0.92 117 23 67° 49' N 115° 8' W
Taloyoak 851 120 0.92 101 69° 33' N 93° 35' W TOTAL: 29882 3609 3032 469
*Community participated in Inuit Child Health Survey 2007-2008 aSanikiluaq is a community in Baffin Region, but given its geographical proximity to Kivalliq region, it will grouped with Kivalliq communities for statistical analyses
59
Table 4-2. Inuit Child Health Survey 2007-2008 data collection schedule. Community Date Sanikiluaq August 8, 2007 – August 10, 2007 Pond Inlet September 26, 2007 – September 30, 2007 Igloolik October 2, 2007 – October 5, 2007 Clyde River October 8, 2007 – October 11, 2007 Pangnirtung October 13, 2007 – October 18, 2007 Iqaluit October 19, 2007 – October 28, 2007 Kimmirut October 29, 2007 – November 1, 2007 Rankin Inlet November 2, 2007 – November 9, 2007 Coral Harbour November 9, 2007 – November 13, 2007 Chesterfield Inlet November 14, 2007 – November 16, 2007 Arviat November 17, 2007 – November 21, 2007 Whale Cove November 21, 2007 – November 23, 2007 Cambridge Bay August 21, 2008 – August 23, 2008 Kugluktuk August 25, 2008 – August 28, 2008 Kugaaruk September 1, 2008 – September 3, 2008 Baker Lake September 3 – September 9, 2008
60
Table 4-3. Descriptions of measured outcome and exposure variables.
Variable Description Variable type Anemia a -Ages 3 to 4 years: anemic (Hb < 110 g/L),
non-anemic (Hb ≥ 110 g/L) -Ages 5 years and older: anemic (Hb <115 g/L), non-anemic (Hb ≥ 115 g/L)
Binomial: anemic = 1, non-anemic = 0
Iron Deficiency
-WHO cut-off a: iron deficient (ferritin < 12µg/L, non-iron deficient (ferritin ≥ 12 µg/L) -Alternative cut-off b: iron deficient (ferritin < 10µg/L), non-iron deficient (ferritin ≥ 10 µg/L)
Binomial: Iron deficient = 1, non-iron deficient = 0
Iron deficiency anemia (IDA)
-IDA: low ferritin coupled with low hemoglobin, no IDA: normal ferritin and/or normal hemoglobin
Binomial: IDA = 1, no IDA = 0
Acute inflammation
-Standard cut-offc: acute inflammation (CRP > 8ng/ml), no inflammation (CRP ≤ 8 ng/ml)
-Alternative cut-offd: acute inflammation (CRP > 3 ng/ml), no inflammation (CRP ≤ 3 ng/ml)
H. pylori exposure
-No exposure to H. pylori, exposure to H. pylori, indeterminate results coded as missing
Binomial: exposure = 1, no exposure = 0
Household crowding
-Crowding (above median people/home), no crowding (below median people/home)
Binomial: crowding = 1, no crowding = 0
Food Insecurity
-Evidence of child hunger (affirmative response on ≥ 5 child-specific questions from the USDA food security module), no evidence of child hunger (affirmative response on ≤4 child-specific questions from the USDA food security module)e
Binomial: evidence = 1, no evidence = 0
Region Kivalliq, Baffin or Kitikmeot region Categorical Age 5 years (≥ 5.00 years)
4 years (4.00 – 4.99 years) 3 years (<4.00 years)
Categorical and Binomial: 5 years = 0, 3 to 4 years = 1
Sex Male or female Binomial: male = 1, female = 0
Dietary iron intake
Adjusted iron intake in milligrams from 24-hour and repeat 24-hour dietary recall data
Continuous
Anthropometry BMI-for-age: Overweight (>95th ile), at risk for overweight (85-95th %ile), normal weight (5th-85th %ile), underweight (<5th%)f
Categorical and continuous
a From [28] b From [44] c From [51, 52] d From [50, 53] e From [144] f From [145]
61
5 MANUSCRIPT
Low prevalence of iron deficiency anemia among Inuit children ages 3 to 5 years,
living in Nunavut
Angela Pacey1 and Grace M. Egeland1
1Centre for Indigenous Peoples’ Nutrition and Environment, School of Dietetics and
Human Nutrition, McGill University
Corresponding Author and for Reprints:
Dr. Grace Egeland, PhD
Centre for Indigenous Peoples’ Nutrition and Environment, MacDonald Campus
McGill University
Ste. Anne-de-Bellevue, QC, H9X 3V9, Canada
Telephone: (514) 398-7757 Facsimile: (514) 398-1020
E-mail: [email protected]
62
Abstract
Objectives: To report the prevalence of iron deficiency and iron deficiency anemia (IDA)
and to identify key risk factors among Inuit children living in Nunavut.
Design: In a cross-sectional study, usual iron intake was assessed using a 24-hour dietary
recall and a sub-sample of repeat recalls. Interviews were conducted regarding household
demographic characteristics, food security and frequency of meat and cereal intake.
Anthropometric measurements were taken and blood samples were collected for the
measurement of hemoglobin (Hb), ferritin, C-reactive protein (CRP), and antibodies to
Helicobacter pylori (H. pylori)
Setting: Sixteen Inuit communities in Nunavut Territory, Canada.
Subjects: Three hundred eighty-eight Inuit children aged 3 to 5 years.
Results: Anemia (3 to 4 years: Hb < 110 g/L, 5 years: Hb < 115 g/L) was prevalent in
20.3% of children. The prevalence of iron deficiency (ferritin < 12 µg/L) was 19.2% of
children and IDA was 4.4%. When iron deficiency was defined as ferritin less than 10
µg/L, 10.3% of children were iron deficient and 2.6% were iron deficient anemic. Iron
intake was adequate as only 0.3% of children had usual iron intakes below the estimated
average requirement (EAR). Exposure to H. pylori, food insecurity and household
crowding were not associated with iron deficiency or IDA. However, 5 year olds were
less likely to be iron deficient than 3 to 4 year olds (RR = 0.40, 95% CI: 0.19-0.86). Boys
were more likely to be iron deficient than girls (RR = 3.5, 95% CI: 1.09-11.2). In a
multiple logistic regression model, boys were independently more likely to be iron
deficient (Age adjusted OR: 2.87, 95% CI: 1.21 – 6.81).
Key words: iron deficiency, anemia, Aboriginal, Inuit, iron, Helicobacter pylori
63
Introduction
In infants and children, iron deficiency anemia (IDA) can have serious health
consequences including impaired growth and cognitive development and weakened
immune defense [15, 28, 30]. Iron deficiency typically exists in three stages: low iron
stores, reduced iron delivery to the tissues and IDA characterized by low hemoglobin and
reduced erythrocyte size [20]. ‘Aboriginal people’ is a collective name for the indigenous
peoples of Canada including Inuit, First Nations and Dene/Métis [4]. It is believed that
Inuit children have a higher prevalence of iron deficiency than non-Aboriginal children.
However, the most recent estimates for infants and children combined is 24% for tissue
iron deficiency and 5% for anemia from all causes [60]. More recent estimates for the
prevalence of iron deficiency and IDA among Inuit infants are 36 to 60% for iron
deficiency compared to 33% for non-Aboriginal Canadian infants [45, 46, 51]. IDA is
thought to affect 26% of Inuit infants compared to 5% for non-Aboriginal infants [45, 46,
51]. Current information on iron deficiency and IDA among Canadian Inuit children in
the preschool age group of 3 to 5 years is not available.
Key risk factors for iron deficiency in this group may include low dietary iron intake
or infection with the human pathogen Helicobacter pylori (H. pylori). Previous studies
show that iron intake is likely adequate among Inuit children [51, 56, 70, 74]. However, a
nutrition transition in the Arctic is occurring rapidly so current dietary information for
this age group that can be matched with iron status will be useful to obtain. In addition,
infection with H. pylori has been recently shown to cause iron deficiency although the
exact mechanism remains unclear [51, 56, 70, 74, 109, 110, 119, 121, 123-127]. This
pathogen is highly prevalent in most Inuit populations and may increase risk for iron
deficiency among children [51, 59, 84, 101]. Understanding the relationship of these risk
factors with iron deficiency and IDA among Inuit children may be used to direct future
health care planning. Therefore, we completed a cross-sectional survey of Inuit children
in Nunavut that examined the iron status in the preschool age group, risk of inadequate
iron intake as well as risk factors for iron deficiency.
64
Experimental Methods
Setting
This study is part of an Inuit Child Health Survey (ICHS) for preschool children in
Nunavut, Canada. Sixteen of the 25 communities in Nunavut were selected to participate
in the ICHS. Communities were selected based upon region, population size, latitude, and
then finally logistical feasibility due to flight routes and financial constraints. Using
currently available population census information, we estimated that a sample of 20% of
3 to 5 year olds in each community would achieve the sample size goal of 300
considering that some caregivers would refuse venous puncture. Inuit children, ages 3 to
5, were randomly selected to participate in the survey. Recruiters were instructed to make
three attempts to reach households. Written informed consent was obtained from the
child’s caregiver and the process was accompanied by a DVD guide, which was a word-
for-word reading of the consent form, accompanied by photographs and video-clips
relevant to the study.
The ICHS for Nunavut was developed by a steering committee of Inuit organizations
and Canadian universities. Steering committee members helped to develop and review
questionnaires and clinical methods. They reviewed the informed consent and DVD
consent form, as well as coordinated the translations of materials into Inuktitut and
Inuinnaqtun. Research agreements were signed between communities and the research
centers. Certification of Ethical Acceptability for Research Involving Human Subjects
was obtained from the McGill Faculty of Medicine Institutional Review Board. A
Scientific Research License was obtained from the Nunavut Research Institute.
Anthropometry
A nurse measured height to the nearest 0.1 cm using a portable stadiometer (Road Rod
214 Portable Stadiometer, Seca, Maryland) and weight to the nearest 0.1 kg using an
electronic scale. BMI-for age, height-for-age and weight-for-age were calculated using
2000 Centers for Disease Control (CDC) reference growth curves [145]. Overweight was
65
classified as being ≥95th%ile. At risk for overweight was classified as being ≥85th%ile
and <95th%ile. Underweight was classified as being <5th%ile.
Iron status and exposure to H. pylori
Venous or capillary sampling was used to obtain blood samples. When venipuncture was
used, 3 mL of blood was collected into sodium heparin Vacutainer® blood (Becton
Dickinson and Company, Franklin Lakes, New Jersey). The vacutainer tube was inverted
gently 10 times. One drop of whole blood was dispensed onto Parafilm (Pechiney,
Chicago, Illinois) using a Diff-Safe® blood dispenser (Alpha Scientific Corporation,
Southeastern, PA). Hemoglobin was measured either from this drop or from capillary
blood samples using the cyanmethemoglobin method with HemoCueTM 201+ portable
photometer (HemoCue, Inc., Lake Forest, California). Blood samples were centrifuged
within 6 hours of collection. Separated plasma was stored at minus 20°C during field
work and at minus 80°C after completion of data collection.
Serum ferritin was measured from plasma samples using an autoanalyzer (Liason®,
DiaSorin, Saluggia, Italy) and a ferritin integral (REF 313551, DiaSorin, Saluggia, Italy).
Low, normal and high control samples were tested with each analysis. In the first year of
data collection, CRP was measured in plasma samples using a CRP (Human) Enzyme
Linked Immunosorbance Assay (ELISA) (2007: Pheonix Pharmaceuticals, Inc.,
Burlingame, California). One sample and control were plated in triplicate and all CVs
were under 10%. In the second year of data collection, plasma samples were sent out for
CRP analyses due to time and labour constraints. They were sent to a clinical diagnostic
laboratory at the Montreal General Hospital. A qualitative ELISA (Pylori Detect IgG,
Calbiotech, Spring Valley, California) was used to analyze plasma samples for the
presence of anti-H. pylori IgG.
Iron deficiency was defined as low ferritin (< 12 µg/L) and anemia was defined as low
hemoglobin (Hb < 110 g/L in 3 to 4 year olds, Hb < 115 g/L in 5 year olds) [28]. IDA
was defined as the presence of low ferritin coupled with low hemoglobin. Because the
cut-off value for low ferritin in children is unclear, we also conducted analyses using
ferritin < 10 µg/L to define iron deficiency [44, 46].
66
Dietary intake
One 24-hour dietary recall was conducted for each child participant by training
interviewers using a four stage, multiple pass interviewing technique. Food model kits
were used to estimate portion sizes. Depending on the number of days spent in the
community, all caregivers from the first or second day of appointments were asked to
return to complete a repeat 24-hour dietary recall on a nonconsecutive day. We collected
a 20% sub-sample of repeat 24-hour dietary recalls. Interviewers also asked about the
child’s mineral and vitamin supplement use. Each caregiver was asked to complete a
qualitative food frequency questionnaire (FFQ) for their child. The FFQ was designed to
capture past month information about common country foods that are available in the
three regions of Nunavut. It also included beef, fish, poultry, pork and breakfast cereal to
capture commercially available market food sources of iron containing foods. Caregivers
were asked about how often the child ate the foods in the past month. Food frequency
information was entered using EpiInfo and data were double verified. Twenty-four hour
dietary recall information was entered using CANDAT. Nutrient composition of foods
was determined using the Canadian Nutrient File and a USDA Institution file. All 24-
hour recalls were double verified.
The home environment
Interviewers asked questions about age, sex and relationships of everyone in the child’s
household. They also conducted questionnaires for characteristics of the home including
the USDA 18-item Household Food Security Survey Module adapted for Inuit
populations [69, 144]. From the food security module, homes were classified as having
“evidence of children hunger” when 5 or more affirmative responses on child-specific
questions were given.
Statistical analyses
Prevalence rates and 95% CIs of anemia, IDA and iron deficiency were estimated as the
proportion of participating children presenting with the condition. Usual iron intake from
24-hour recall was estimated from observed intake using Software for Intake Distribution
67
Estimation (SIDE) developed by Iowa State University. Within-person variability was
estimated using information from the 20% sub-sample of repeat recalls. The percentage
of children below the age-appropriate EAR for iron was determined. The frequency of
consumption in number of days per month was calculated, both for consumers only and
for all children, for iron containing traditional Inuit foods and commercially available
market foods.
Bivariate analyses of outcome and risk factors as well as region, age and sex were
performed using Chi-squared test and Fisher’s exact test when cell size were less than 10
children. Relative Risks (RR) and 95% confidence intervals were calculated for each of
the exposure variables when p < 0.05. Multiple logistic regression was performed to
examine independent effects of risk factor variables. For all analyses, a p-value less than
0.05 was considered significant.
Analyses were repeated using a low CRP cut-off because of the uncertainty of CRP
reference values in children [50, 53]. Finally, we compared hemoglobin concentrations
from finger prick samples to venous blood samples to assess measurement error from
different sampling techniques.
Dietary adequacy analyses were determined using SIDE in SAS version 9.1. All other
analyses were performed using Stata 10 (Stata Corp, Texas). Anthropometric analyses
were performed in EpiInfo Nutrition Version 6.
Results
Of the 644 households that were initially approached, 537 were successfully contacted
and overall, while 16.6% of homes were not reached. Of homes that were successfully
contacted, 75 (11.6%) refused upon initial contact and 74 (13.8%) accepted, but later
cancelled or did not show for the interview. The final participation rate was 72.3% (388)
children over the two years of data collection.
68
Population characteristics
Fifty-three percent of the participating children were female and the mean age was 4.4 ±
0.9 years (Table 5-1). Thirty-seven percent of the children were from Kivalliq region,
44% from Baffin region and 19% from Kitikmeot region. Fifty-two percent of the
children’s homes were crowded with six or more people per home and the mean number
of people per bedroom was 2.1 ± 0.7. Evidence of hunger among children was found in
23.5% of the homes. Forty-three percent of the child participants lived in a home where
there was a younger child. Children had high rates of overweight (50.8%) and many were
at risk for overweight (27.3%). Underweight was found in 0.5%. Height-for-age and
weight-for-age were normally distributed (Shapriro-Wilk test p = 0.07 for both). The
median height-for-age was in the 49.6th percentile, which is close to the median for the
reference population. However, the median weight-for-age was at the 85.2nd percentile,
which is a large upward shift from the reference population, indicating that high weight-
for-age and not short height-for-age is behind the high rates of overweight among the
sample population. Children’s multi-vitamin and mineral supplements were consumed by
11.9%. Those with added iron were consumed by 2.6% of children.
We obtained venous blood from 289 out of 388 children (74.7%). Capillary blood
samples for hemoglobin were obtained for 79 out of 388 children (20.4%). Nineteen
children did not undergo venous or capillary blood sampling (4.9%). Reasons included
refusal by child or caregiver, skin infection or inability to obtain vein for sampling.
Hemoglobin values were obtained for 364 of the 388 participating children. H. pylori
status was measured for 289 samples and 7 samples with indeterminable results were
excluded from analyses. Plasma ferritin was determined for 283 samples and not
measured on 7 samples due to low sample volume. CRP was quantitatively determined
for 257 children. Twenty-seven children had concentrations below the detection limit
(0.05 ng/ml in first year, 0.20 ng/ml in second year) and were thus considered to be
below the cut-off. Three samples had CRP concentrations above the detection limit after
attempting three assays with different dilutions. These were considered to be above the
cut-off for elevated CRP.
69
Overall, 4.2% (12/286) had CRP concentrations greater than 8 ng/ml. These children
were excluded from analyses involving ferritin. The mean CRP concentration was 2.95
ng/ml and the median was 0.80 ng/ml among the participating children (n = 287).
Iron status
Mean ferritin concentration for all children was 19.9 µg/L (n = 283). For only children
with low CRP, the mean ferritin concentration was 19.3 ± 10.3 µg/L (n = 271, Table 5-2).
Mean hemoglobin was 118 ± 9 g/L and 117 ± 8 g/L among the 3 to 4 year olds and 5 year
olds respectively. Mean hemoglobin for all ages was 117 ± 9 g/L.
Overall, 19.2% of children were iron deficient (Table 5-3). Using a ferritin cut-off of
10 µg/L, the prevalence of iron deficiency decreased to 10.3%. Anemia from all causes
was found in 20.3% of the study population. IDA was found in 4.4% of children but
when the lower ferritin cut-off was used, IDA prevalence decreased to 2.6% of children.
Iron deficiency explained 30.8% of the observed anemia while the remaining anemia
(69.2%) was likely due to other causes. When the lower ferritin cut-off was used, iron
deficiency explained only 18.0% of anemia. Among the children with anemia, 17.9%
(65/364) had Hb ≥ 100 g/L, but below the age-specific cut-off, otherwise known as mild
anemia. Hemoglobin < 100 g/L was observed in 2.5% (9/364). H. pylori exposure was
found in 45.4% of children (Table 5-3).
Dietary iron intake
Iron intake appeared to be normally distributed with a mean of 15.6 ± 10.9 mg/day and
median of 13.5 mg/day (Figure 5-1, Table 5-4). Only 0.3% of children had iron intakes
below their age-specific EAR. Mean vitamin C intake was 229 ± 329 mg/day and only
0.14% had intakes below the EAR for vitamin C.
Based on analysis of the qualitative FFQ, the most commonly consumed traditional foods
were caribou meat (84.2% of children), fish (65.3%) and ringed seal meat (49.5%) (Table
5-5). On average, among those who consumed the food in the past month, children ate
caribou on 11.8 days of the month. They ate fish on 7.1 days of the month and ringed seal
meat was eaten on 4.4 days of the month. With respect to iron containing market foods,
70
96.3% of the children ate breakfast cereal and among these, they ate it on 28.9 days of the
month on average. Beef was consumed by 82.6% of children on 10.4 days per month on
average.
Risk factors for iron deficiency and IDA
Exposure to H. pylori, child hunger and having a younger sibling and household
crowding were examined as risk factors for iron deficiency and IDA, using ferritin cut-off
values of 10 µg/L and 12 µg/L. Age, sex and region were also examined for possible
associations. The proportions of children with iron deficiency or IDA were similar,
regardless of exposure to the risk factors investigated (Table 5-6). However, at the lower
ferritin cut-off, both age and sex were significantly associated with iron deficiency but
not IDA. Boys were more likely to be iron deficient than girls (RR = 2.75, 95% CI: 1.26-
6.03). Children aged 3 to 4 years were more likely to be iron deficient (RR: 3.37, 95%
CI: 1.05-10.83). We performed post-hoc tests for differences in mean dietary iron intake
between sex and age groups. There were no differences in mean intake between boys
(15.5 ± 5.8 mg) and girls (15.6 ± 6.1 mg) (p = 0.805). Similarly, there were no mean
intake differences between 3 to 4 year olds (15.3 ± 5.4 mg) and 5 year olds (16.3 ± 7.2)
(p = 0.164). We noticed that BMI-for-age was significantly higher in 3 to 4 year olds (z =
1.66) than in 5 year olds (z = 1.33) (p < 0.001). However, here were no significant
differences in BMI among iron deficiency or IDA groups or based on sex.
In fully adjusted multiple logistic regression models containing all risk factor variables
and age and sex, only sex was independently associated with iron deficiency defined as
ferritin less than 10 µg/L (Fully adjusted OR = 2.62, 95% CI: 1.08-6.38, p = 0.034). In a
post-hoc model containing only age and sex, sex remained associated with iron
deficiency (Age adjusted OR: 2.87, 95% CI: 1.21 – 6.81).
Intercorrelation between independent variables
Investigation of intercorrelation between independent variables revealed that household
crowding was significantly associated with having a younger child in the home (p <
0.001). Sixty-three of 182 homes had a younger child and were not crowded (34.6%)
71
whereas 104 of 195 homes had a younger child and were crowded (53.3%). In addition,
infection with H. pylori was associated with Nunavut region in bivariate analyses.
Kitikmeot had a higher prevalence of 62.8% (32/51) than Baffin (39.0%, 53/136) or
Kivalliq regions (45.3%, 43/95) (X2=8.4587, p = 0.015). No other independent variables
were significantly correlated.
Differences in capillary and venous blood hemoglobin
The mean Hb concentration when using capillary blood samples (114.2 g/L, n=79) was
significantly lower (p < 0.001) than the mean Hb concentration when using venous blood
samples (118.3 g/L, n = 285). Because of this, we reassessed anemia and iron status using
only the venous blood samples. The prevalence of anemia then decreased somewhat to
16.5%. However, the prevalence of IDA did not change. Bivariate analyses were re-
analyzed including only venous blood samples and no change was seen in the results.
Alternative CRP cut-off value
The above prevalence rates were determined using CRP < 8 ng/mL to determine valid
ferritin measures. We also used a CRP cut-off of 3ng/mL to indicate acute inflammation
in children. High CRP was found in 21.3% at this cut-off level. Among the remaining
children with low CRP, the mean ferritin concentration was 18.9 µg/L (n = 225). This is
similar to the mean ferritin concentration determined from children with CRP less than 8
ng/mL (19.3 µg/L). At the lower CRP cut-off, the prevalence of iron deficiency was
20.9% (95% CI: 15.8-26.8%) and IDA was 5.0% (95% CI: 2.5-8.7%), which is similar to
prevalence rates determined using the higher CRP cut-off. Bivariate analyses also did not
change at this cut-off, but IDA was no longer associated with any of the risk factor
variables.
Discussion
The low prevalence rate of IDA among Nunavut’s preschoolers is encouraging. Previous
studies have reported high rates of IDA and anemia among Canadian Inuit infants and the
current findings reveal that the slightly older age groups are less affected [45, 51, 56]. It
is concerning that iron deficiency defined by low ferritin is more common among Inuit
72
preschoolers and than American preschoolers. In the United States, iron deficiency is
prevalent among 4.5% of children aged 3 to 5 years, compared to 10.3% to 19.2% in
Nunavut [64]. IDA is found among 0.5% of American children while 2.6% to 4.5% of
Nunavut’s preschoolers are affected [64]. More rigorous measures were used to define
iron deficiency in the United States. As such, a lower rate of iron deficiency would be
expected. However, the gap is quite large and this trend where Inuit children have higher
rates of iron deficiency has been observed before in a nutrition survey in Canada, with
Alaska Natives as well as with Canadian Inuit infants [45, 46, 51, 59, 60, 64]. The
prevalence rates determined from this study would likely be defined as mild according to
WHO thresholds for population-level iron deficiency [27]. Since they continue to be
higher among Inuit compared to the general population, and improvements are possible.
Iron intake in this population is probably adequate since only 0.3% of children had
intakes below the EAR. In addition, beef, breakfast cereals, most of which are iron-
fortified and caribou were frequently consumed in this population. Vitamin C intake is
also probably adequate suggesting that reduced absorption of non-heme iron is not likely.
While over-reporting of portion sizes on 24-hour dietary recalls is possible, the mean and
median intake levels are similar in this study compared to others in Inuit children,
Dene/Métis children and American children overall [56, 66, 70, 149].
However, given that iron deficiency was found more in children aged 3 to 4 years than
in 5 years, perhaps dietary differences between these age groups explain this finding. For
example, high consumption of cow’s milk and evaporated milk was an independent risk
factor for iron deficiency in Inuit infants [51]. This risk factor may continue to play a role
in early childhood but requires further investigation. However, the finding that boys were
more at risk than girls is difficult to explain given that there were no differences in
dietary intake between the two groups.
One possible explanation for the finding that more boys than girls and more 3 to 4
year old than 5 year olds were iron deficient may be related to BMI-for-age. It has
recently been shown that obesity and being overweight is associated with greater risk of
iron deficiency, perhaps due to low diet quality, increased iron requirement due to higher
73
blood volume as well as decreased iron absorption induced by chronic low grade
inflammation [150-154]. Although there were no significant associations between iron
deficiency and BMI-for-age in the current study, we noticed that more 3 to 4 year olds
than 5 year olds were overweight and even though it was not significant, there was a
tendency for more boys to have higher BMI-for-age z scores than girls. Perhaps iron
deficiency is more prevalent among younger children and boys because of higher rates of
overweight and at risk for overweight in these groups. In addition, we may have been
limited in our sample size in detecting associations between BMI-for-age and iron
deficiency.
The 45.4% prevalence of H. pylori exposure observed in this study is high and
consistent with other studies with Canadian First Nations and Inuit and Alaskan Native
children [51, 59, 84, 101, 102]. Much lower rates of 5.5% to 7.1% have been reported for
American and Canadian children [64, 100]. It should be noted that using serodiagnosis to
measure H. pylori only allows us to estimate previous exposure, and not current infection
and may underestimate the prevalence of H. pylori infection in this age group [93-95].
H. pylori has been previously shown to be independently associated with iron
deficiency in other populations including Inuit [59, 64]. In the United States, it was
reported that H. pylori was independently associated with IDA (OR: 2.6, 95% CI: 1.5-
4.6), but not iron deficiency alone for children and adults older than 3 years [59, 64].
Among Alaska Native, H. pylori was only independently associated with iron deficiency
and not IDA for children in the 9 and older age group, and not in younger age groups
[59]. In addition, many case reports from which evidence for this association first
emerged involved mostly children in the 9 to 15 year old age group [116, 123-126]. It is
perhaps this age-dependent association that may explain why among Inuit preschoolers,
there was no association between H. pylori and iron status. The mechanism by which H.
pylori induces iron deficiency is still unclear but may be related to bacterial damage to
gastric glandular tissue and iron competition in the stomach [109, 111, 112, 119-121]. If
these are indeed the mechanisms, perhaps younger children who are more recently
infected, are more protected than older children who have more established infections.
74
Finally, in the current study, anemia from all causes was found in 16.5% of Inuit
children and only 18.0 to 30.8% of anemia was explained by low iron status. Other
studies in children and infants have shown similar results where only a portion of the
observed anemia is explained by iron deficiency [36, 37, 155]. A possible explanation for
this finding is the presence of acute infection, where red blood cell half-life is decreased
and the acute phase response block iron export proteins trapping iron inside cells [17,
156, 157]. Other dietary causes of anemia include deficiencies in vitamin A, folate, B12
and riboflavin [35]. Given the high meat and cereal intake from food frequency
information, these micronutrient deficiencies are unlikely.
Limitations
The present study had a cross-sectional design that allowed us to report observations but
not causal relationships. With only a sub-sample of repeat dietary recalls, we can only
estimate usual intake in this population and have no measure of each individual’s usual
intake. The limitations to using serodiagnosis for H. pylori were noted above.
Conclusion
Inuit children aged 3 to 5 years, have higher rates of iron deficiency, IDA and anemia
than non-Aboriginal children. However, these rates are not so high that they suggest a
need for immediate intervention. Instead, we should consider the practices in Nunauvt’s
communities that are helping to prevent iron deficiency in many children in addition to
where public health policies can be improved. This study also revealed that iron
deficiency explains only 18.0 to 30.8% of low hemoglobin. As such, low hemoglobin
findings among Inuit children likely need additional assessments to better understand the
etiology. Finally, young Inuit children have adequate iron intake. Careful work is needed
to address the high prevalence of overweight while maintaining these good iron intakes
among young Inuit children exposed to the nutrition transition in the Arctic.
Acknowledgements
This study was funded though Government of Canada International Polar Year, Canadian
Institutes for Health Research and the Government of Nunavut Department of Health and
75
Social Services. We acknowledge the work of Nancy Faraj, Christine Ekidlak, Laureen
Angalik Kathy Morgan, Nelofar Sheikh and Louise Johnson-Down.
76
Table 5-1. Population and household characteristics.
n/N % Sex Female 204 / 388 52.6 Male 184 / 388 47.4 Age 3 to 3.99 y 158 / 388 40.7 4 to 4.99 y 123 / 388 31.7 5 to 5.99 y 107 / 388 27.6 Region Kivalliq 142 / 388 36.6 Baffin 171 / 388 44.1 Kitikmeot 75 / 388 19.3 BMI-for-age (n=378) Overweight 192 / 378 50.8 At risk of overweight 103 / 378 27.3 Normal weight 81 / 378 21.4 Underweight 2 / 378 0.5 Household characteristics Younger child in the home 169 / 388 43.6 (38.6 – 48.7)a Household crowding (≥ 6 people) 195 / 377 51.7 (46.6 – 56.9)a Food insecurity 88 / 374 23.5 (19.3 – 28.2)a a 95% Confidence Interval (%)
77
Table 5-2. Summary of serum ferritin and hemoglobin concentrations for Nunavut and by region.
Nunavut Kivalliq Kitikmeot Baffin Meana 95% CI Min Max Median n Meana n Meana n Meana n
Ferritin (µg/L)b 19.3 (10.3) 18.1 – 20.6 3.2 78.9 16.6 271
20.4 (10.8) 99
20.5 (14.8) 43
18.2 (7.8) 129
Hb (g/L):
All ages 117.4 (9.0) 116.5 – 118.3 82 145 118 364
116.6 (9.3) 136
118.9 (9.0) 72
117.4 (8.8) 156
5 yc 117.8 (8.1) 116.2 – 119.5 85 137 118 99
118.0 (8.0) 40
117.5 (6.4) 23
117.0 (9.3) 36
3 to 4 yc 117.2 (9.4) 116.1 – 118.4 82 145 118 265
116.1 (9.8) 96
119.5 (10.0) 49
117.2 (8.7) 120
a Standard deviation shown in brackets b Ferritin below 10 µg/L or 12 µg/L is considered iron deficiency in children [28, 44]. c Hemoglobin less than 115 g/L is anemia in 5 year olds, and less than 110 g/L is anemia in 3 to 4 year olds [28].
78
Table 5-3. Prevalence of iron deficiency, anemia, iron deficiency anemia and Helicobacter pylori infection among participating children.
Nunavut Regional prevalence n/N Prevalence 95% CI Kivalliq Baffin Kitikmeot Ferritin < 12 µg/L: Iron deficiency 52 / 271 19.2% 14.7 – 24.4% 19.2% 20.2% 18.6%
Iron deficiency anemiaa 12 / 267 4.5% 2.3 – 7.7% 6.1% 4.8% 0
Ferritin < 10 µg/L: Iron deficiency 28 / 271 10.3% 7.0 – 14.6% 10.1% 10.1% 14.0%
Iron deficiency anemiaa 7 / 267 2.62% 1.1 – 5.3% 3.0% 3.2% 0
Anemiab 72 / 364 20.3% 16.3 – 24.9% 22.8% 19.2% 18.1%
H. pylori infection 128 / 282 45.4% 39.5 – 51.4% 45.0% 39.0% 62.7%
a Presence of anemia coupled with iron deficiency b Hemoglobin < 110 g/L (3 to 4 years) or < 115 g/L (5 years)
79
Table 5-4. Mean, median and percentage of individuals with intakes below the EAR, not including supplements, for energy, vitamin C and iron in Inuit children, ages 3 to 5 years (n = 374).
Nutrientb Mean ± SD intake
Median intake
% individuals below EAR
EARa RDAa
Energy – kcal 1875 ± 791 1819 NA NA NA
Vitamin C – mg 229 ± 329 202 0.14 13 – 22 15 – 25
Iron – mg 15.6 ± 10.95 13.53 0.27 3.0 – 4.1 6 – 10 aEAR = estimated average requirements; NA = not applicable; RDA = recommended daily allowance bNutrient adjusted using SIDE software (Iowa State University 1996). Adjustments made for sequence and day of week. Where appropriate, this software also provides the number below the EAR.
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Table 5-5. Frequency of consumption of traditional and market food sources of iron among Inuit children, ages 3 to 5 years.
Percentage of 3 to 5 year olds who
consumed the food in the past month
Average number of days consumed in a month
% n / N Consumers
only All children Traditional foods:
Caribou meat (dried, cooked, raw) 84.2 320 / 380 11.8 10.0 Fish, all types 65.3 248 / 380 7.1 4.6 Ringed seal meat 49.5 188/ 380 4.3 2.2 Clams/mussels from the land 15.5 59 / 380 3.2 0.5 Goose 14.7 45 / 307a 2.9 0.4 Ringed seal liver 11.6 44 / 380 3.8 0.4 Duck, all types 10.8 41 / 380 2.2 0.2 Walrus meat 8.6 29 / 336a 2.0 0.2 Musk-ox meat 6.0 8 / 133a 1.7 0.1 Caribou liver 5.0 19 / 380 5.4 0.3 Beluga meat 4.5 17 / 380 2.5 0.1 Ptarmigan and spruce hen 3.7 14 / 380 2.3 0.1 Narwhal meat 2.9 11 / 380 6.0 0.2
Market foods:
Cereal, all types 96.3 366 / 380 28.9 27.8 Beef, all types 82.9 315 / 380 10.4 8.5 Poultry, all types 82.6 314 / 380 8.5 7.0 Pork, all types 69.7 265 / 380 8.0 5.6
a Because of limited geographical availability of this food, N is reduced because certain communities were not asked about this traditional food item.
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Table 5-6. Bivariate analyses of explanatory factors for iron deficiency and iron deficiency anemia using two different ferritin cut-off values to define iron deficiency.
Ferritin < 12 µg/L Ferritin < 10 µg/L Iron deficiency IDAa Iron deficiency IDAa N % (n) p N % (n) p N % (n) p N % (n) p H. pylori Positive 146 15.3 (18) 0.09 117 1.7 (8) 0.07 146 8.5 (10) 0.31 117 1.7 (8) 0.46 Negative 118 24.0 (35) 143 7.0 (10) 118 12.3 (18) 143 3.5 (5) Household size ≥6 134 17.2 (23) 0.64 133 6.0 (8) 0.22 134 10.5 (14) 0.92 133 4.5 (6) 0.12 <6 129 20.2 (26) 126 2.4 (3) 129 10.1 (13) 126 0.8 (1) Younger sibling No 151 21.8 (33) 0.36 147 5.4 (8) 0.56 151 8.3 (10) 0.34 147 2.7 (4) 1.00 Yes 120 16.7 (20) 120 3.3 (4) 120 11.9 (18) 120 2.5 (3) Child hunger Yes 64 20.5 (40) 0.47 63 8.0 (5) 0.15 64 10.9 (7) 0.82 63 6.4 (4) 0.07 No 195 15.6 (10) 192 3.1 (6) 195 10.3 (19) 192 1.6 (3) Region Kivalliq 99 19.2 (19) 1.00 99 6.1 (6) 0.35 99 9.1 (10) 0.69 99 3.0 (3) 0.77 Baffin 129 20.2 (26) 125 4.8 (6) 129 10.1 (13) 125 3.2 (4) Kitikmeot 43 18.6 (8) 43 0 43 14.0 (6) 43 0 Sex Male 129 21.7 (28) 0.45 126 4.8 (6) 0.83 129 15.5 0.01 126 4.8 (6) 0.06 Female 142 17.6 (25) 141 4.3 (6) 142 5.6 (8) 141 0.7 (1) Age 3-4 years 193 22.3 (43) 0.09 190 4.2 (8) 0.75 193 13.0 (25) 0.03 190 3.2 (6) 0.68 5 years 78 12.8 (10) 77 5.2 (4) 78 3.9 (3) 77 1.3 (3) a IDA – Iron deficiency anemia
83
6 DISCUSSION
This is the first study to report population level prevalence estimates of iron deficiency
and IDA for Inuit preschoolers in Nunavut, Canada. The prevalence of IDA was low in
the study population but overall, it seems that the iron status of Inuit preschoolers is
worse than that of North American children. In the United States, iron deficiency is
prevalent among 4.5% of children aged 3 to 5 years and IDA among 0.5% [64]. These
compare to rates of 10.3% to 19.2% for iron deficiency and to 2.6% to 4.5% of IDA,
among Inuit preschoolers observed in the present study.
This trend where Inuit have higher rates was observed in a 1970-1972 national
nutrition survey in Canada, albeit only small sample of 29 Inuit children was included
[60]. In this study, the prevalence of tissue iron deficiency was 24% for Inuit children 0
to 4 years, compared to 12% for non-Aboriginal Canadian children [60]. Similarly,
Alaska natives had 38% iron deficiency and 7.8% IDA compared to 4.5% and 0.5% for
American children [59, 64]. Canadian Inuit infants also seem to be more at risk for iron
deficiency than Canadian infants. Low ferritin was found in 36.9% of infants from a
community in Kivalliq region, 60% of infants from a community in Nunavik and 33.9%
of infants from four major Canadian cities [45, 46, 51]. Infants aged 12 months from
Nunavik had a 26.3% prevalence of IDA compared to 5.1% of Canadian infants aged 8.5
to 15.5 months [45, 46, 51].
While Inuit preschoolers appear to be more at risk for iron deficiency than American
children, the prevalence rates reported here are mild. The WHO estimates that 40% of
preschool aged children in lower-income countries are anemic and that 50% of these are
specifically iron deficient anemic, or 20% overall. Prevalence rates for Nuanvut
preschoolers are much lower than this. In addition, the WHO suggested recently that
when low ferritin is found in more than 20% of a population, iron deficiency is said to be
prevalent [27]. At the WHO recommended ferritin cut-off, Inuit preschoolers are just
below this threshold, at 19.2%.
A final approach to interpreting the prevalence findings in this study is to speculate
about whether these have improved or increased over time. The 1970-1972 national
84
nutrition survey in Canada found that 24% of Inuit children 0 to 4 years had tissue iron
deficiency, based on transferrin saturation below 16% [60]. Because transferrin saturation
gives an estimate of a more severe stage of iron deficiency compared to ferritin, low
ferritin will be more common than low transferrin saturation. As such, the prevalence of
tissue iron deficiency is likely less than 19.2% among Inuit preschoolers in 2007 and
2008, which is lower than 24% found in 1972. Although comparing in this way is highly
speculative, it suggests at least that rates have not increased in the past three decades.
Overall, few Inuit preschoolers experience IDA. The prevalence of iron deficiency
continues to be higher among Inuit than in the general population, and as such,
improvements are possible.
Iron intake in this population is probably adequate given the finding that only 0.3% of
children were eating below the EAR, vitamin C intake was high and many children were
consuming traditional and market meats and cereals. On this background of high iron
intake, the finding that 10.3 to 19.2% iron deficiency seems contradictory. It is possible
that there was some over-reporting of traditional food intake, characterized by the high
median and mean iron intake in this young age group. However, iron intake in these
children is similar to previously reported intakes. We reported a mean intake of 15.6
mg/day from all sources of food. A study of Dene/Métis children found that mean iron
intake was 14 to 16 mg/day [66, 70]. In one Nunavut community among children aged 3
to 12 years, mean iron intake was 20 mg/day from traditional food and 10 mg/day from
market food [149]. For all age groups in this study, iron from market food ranged from 8
to 12 mg/day throughout the year and iron from traditional food ranged from 18 to 70
mg/day throughout the year. The 1972 NCNS and a 1995 Keewatin Health Assessment
Survey that took place in 1995 also reported high iron intake among children [56, 60].
Finally, intake estimates from the 2000-2001 NHANES were 11.0 to 13.7 mg per day for
3 to 8 year old children [149]. Since iron intake is similarly high in other studies, perhaps
either there is a consistent trend for iron intake to be overestimated in children, or perhaps
these high intakes are indeed high.
Regardless, there is still a discrepancy between the dietary and biochemical findings,
which is perhaps explained by limitations to dietary interviewing tools. Estimating usual
85
iron intake is challenging in any setting, especially in large epidemiological studies where
the number of repeat recalls collected is often limited by time and logistical constraints.
In the current study, one recall and a repeat recall on a 20% sub-sample was used.
However, it has been suggested that for iron, and other nutrients, a larger number of
repeat twenty-four hour recalls is needed to estimate usual intake [22]. For example,
using the formula developed by Beaton and colleague, for children 1 to 5 years, if one
wanted to estimate usual iron intake within 20% of the real value with 95% confidence,
21 recalls for each individual would be needed [22]. This number increases to 85 in order
to obtain estimates that are within 10% of the real intake value [22]. As such, while iron
intake for 3 to 5 year old Inuit children in Nunavut seems adequate with a high median
intake, these findings cannot rule out diet as a cause of iron deficiency in this population.
Overall, the discrepancy between biochemical findings and dietary findings could be
explained by the lack of sensitivity and specificity of a limited numbers of 24-hour
dietary recalls.
In addition, it was discussed in the previous chapter that high BMI-for-age may
explain the observed iron deficiency. It has recently been shown that obesity and being
overweight is associated with greater risk of iron deficiency [150-154]. Using data from
NHANES 1988-1994, it was found that overweight and at risk for overweight children
were 2.0 to 2.3 times more likely to be iron deficient than normal weight children [152].
Similarly, from NHANES 1999-2000 it was found that overweight and at risk for
overweight toddlers aged 1 to 3 years were 3.34 times more likely to be iron deficient
than normal weight toddlers [150].
Possible explanations for this observation may include lower iron intake among
overweight children, especially from consuming too much juice, milk and high-sugar and
low-iron foods. As well, overweight children may have increased iron requirement due to
larger blood volume and increased basal loss [150, 152, 154]. In addition, it has been
suggested that being overweight may induce chronic low-grade inflammation, signalling
hepcidin release from the liver and adipocytes, reducing iron absorption into the blood
stream from the upper small intestine [154, 158]. Recently, it was discovered that among
female adolescents who are greater than 85th percentile for BMI-for-age, the odds ratio
86
for iron deficiency doubles with each 1 ng/mL increase in CRP [158].
Although there were no significant associations between iron deficiency and BMI-for-
age in the current study, we noticed that more 3 to 4 year olds than 5 year olds were
overweight and there was a tendency for boys to have higher BMI-for-age z scores than
girls. Perhaps iron deficiency is more prevalent among younger children and boys
because of higher rates of overweight and at risk for overweight in these groups. In
addition, we may have been limited in our sample size in picking up any associations
between BMI-for-age and iron deficiency.
The 45.4% prevalence of H. pylori exposure that was found in this study is high and
consistent with other studies. In Canadian Inuit and northern First Nations infants and
children, the prevalence of H. pylori has been reported to be 39% to 56% [51, 59, 84,
101]. In Alaska, rates are also high from 32 to 86% [59, 102]. This is compared to low
rates of 5.5 to 7.1% among children and adolescents in the United States and Canada [64,
100]. It should be noted that using serodiagnosis to measure H. pylori only allows us to
estimate exposure, and not current infection. Current infection should be measured with
more sensitive measures such as urea breath test, endoscopy or stool antigen test, all of
which posed considerable logistical constraints in this study. However, it is believed that
in children, serodiagnosis underestimates prevalence of H. pylori infection [93-95]. As
such, we can estimate that rates are at least 45.4% in this population.
H. pylori has been previously shown to be independently associated with iron
deficiency in other populations including Inuit [59, 64]. In the United States, it was
reported that H. pylori was independently associated with IDA (OR: 2.6, 95% CI 1.5-
4.6), but not iron deficiency alone for children and adults older than 3 years [59, 64].
Among Alaska Native, H. pylori was only independently associated with iron deficiency
and not IDA for children in the 9 and older age group, and not in younger age groups
[59]. It is perhaps this age-dependent association which may explain why among Inuit
preschoolers, there was no association between H. pylori and iron status.
The early case series and case reports where this association was first described
involved mostly children in the 9 to 15 year old age group [116, 123-126]. A recent
87
smaller study of risk factors for iron deficiency in Inuit and First Nations infants found
that only cow’s milk and evaporated milk consumption were the only independent risk
factors, while H. pylori was not independently associated [51].
The mechanism by which H. pylori induces iron deficiency is still unclear but may be
related to bacterial damage to gastric glandular tissue and iron competition in the stomach
[109, 111, 112, 119-121]. If these are indeed the mechanisms, perhaps younger children
who are more recently infected, are more protected than older children who have more
established infections.
One final finding that was interesting was the prevalence of anemia from all causes. In
American children aged 3 to 5 years this was estimated to be 1.5% [59, 64]. In the current
study, anemia from all causes was much higher at 16.5% of Inuit children. In addition,
only 18.0 to 30.8% of anemia was explained by low iron. The WHO estimates that only
50% of anemia is related low iron and our finding is somewhat consistent with this [28].
Other studies in children and infants have shown similar results where only a portion of
the observed anemia is explained by iron deficiency [36, 37, 155]. A possible explanation
for this finding is the presence of acute infection. In acute infection red blood cell half-
life decreases and iron becomes trapped inside cells and is not available for
erythropoiesis, both of which explain the mild anemia associated with acute inflammation
[17, 156, 157]. Other dietary causes of anemia include deficiencies in vitamin A, folate,
B12 and riboflavin [35]. Given the high meat and cereal intake from food frequency
information, these micronutrient deficiencies are unlikely.
Future research might focus on the finding that many children were anemic but not
iron deficient. This was likely related to acute infection but it would valuable to confirm
this, especially since follow-up assessments to low hemoglobin should be done if this
were indeed related so another nutrient deficiency. Other studies might further investigate
the high prevalence of H. pylori exposure by highlighting risk factors or determining
which strains are most common in Nunavut, as more virulent strains are associated with
more severe health outcomes. Finally, perhaps a more pressing research need from a
global health research perspective would include establishing ferritin cut-off values for
children. In this study, the prevalence of iron deficiency changed by about 9% between
88
the two different cut-off values used. With the advent of the HemoCueTM came a method
to measure anemia that was accurate and accessible for populations all over the world.
Assessing iron status is also important because it helps in deciding how to treat low
hemoglobin. Ferritin is promising because it is inexpensive and requires a small sample
of blood. However, as mentioned, current cut-offs are unclear.
Overall, it was observed that Inuit children aged 3 to 5 years, living in Nunavut, have
low rates IDA and rates of iron deficiency from 10.3% to 19.2%. These are still higher
than the general population. However, the etiology of the observed iron deficiency and
IDA is still unclear. H. pylori was not found to be related iron status, and might be
explained by the young age group in this study. The H. pylori prevalence was still quite
high suggesting that children could be at risk later in life for iron deficiency and other
negative health outcomes caused by the bacterium. Dietary iron intake was adequate and
even high, although our measure of usual iron intake was limited. Overall the two
findings of a low prevalence of IDA and adequate iron intake are encouraging for
Nunavut. While public health intervention might aim to bring down the prevalence of
iron deficiency, we should bear in mind the other health issues facing Nunavut’s
preschoolers such as high BMI-for-age, high H. pylori exposure and widespread
childhood food insecurity, all of which emerged in this study but were not explored.
Addressing these may be more pressing, especially by considering new interventions as
well as working to maintain the practices that have led to the overall low prevalence of
IDA in Nunavut’s preschoolers.
89
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93. Oderda, G., A. Rapa, and G. Bona, Diagnostic tests for childhood Helicobacter pylori infection: invasive, noninvasive or both? Journal of Pediatric Gastroenterology & Nutrition, 2004. 39(5): p. 482-484.
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105. Roosendaal, R., et al., Helicobacter pylori and the birth cohort effect: evidence of a continuous decrease of infection rates in childhood. American Journal of Gastroenterology, 1997. 92(9): p. 1480-1482.
106. Rothenbacher, D., et al., Evidence of a rapid decrease in prevalence of Helicobacter pyloriinfection in children of a high risk group living in Germany. European Journal of Pediatrics, 2004. 163(6): p. 339-340.
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108. Bittencourt, P.F., et al., Gastroduodenal peptic ulcer and Helicobacter pylori infection in children and adolescents. Journal de Pediatria, 2006. 82(5): p. 325-334.
109. Ashorn, M., Acid and iron-disturbances related to Helicobacter pylori infection.[comment]. Journal of Pediatric Gastroenterology & Nutrition, 2004. 38(2): p. 137-139.
110. Barabino, A., Helicobacter pylori-related iron deficiency anemia: A review. Helicobacter, 2002. 7(2): p. 71-75.
111. Husson, M., et al., Iron acquisition by Helicobacter pylori: importance of human lactoferrin. Infection and Immunology, 1993. 61: p. 2694-2697.
112. Dhaenens, L., F. Szczebara, and M. Husson, Identification, characterization and immunogenicity of the lactoferrin-binding protein from Helicobacter pylori. Infection and Immunology, 1997. 65: p. 514-518.
113. Luqmani, Y., et al., Expression of lactoferrin in the human stomach. International Journal of Cancer, 1991. 49: p. 684-687.
114. Nakao, K., I. Imoto, and E. Gabazza, Gastric juice levels of lactoferrin and Helicobacter pylori infection. Scandinavian Journal of Gastroenterology, 1997. 32: p. 530-540.
115. Nakao, K., I. Imoto, and N. Ikemura, Relation of lactoferrin levels in gastric mucosa with Helicobacter pylori infection and with degree of gastric inflammation. American Journal of Gastroenterology, 1997. 1997(92): p. 1005-1011.
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116. Barabino, A., et al., Unexplained refractory iron-deficiency anemia associated with Helicobacter pylori gastric infection in children: further clinical evidence. Journal of Pediatric Gastroenterology & Nutrition, 1999. 28(1): p. 116-119.
117. Soybel, D.I., Anatomy and physiology of the stomach. Surgical Clinics of North America, 2005. 85: p. 875-894.
118. Özturk, Y., B. Buyukgebiz, and N. Arslan, Antral glandular atrophy and intestinal metaplasia in children with Helicobacter pylori infection. Journal of Pediatric Gastroenterology & Nutrition, 2003. 37(19): p. 96-97.
119. Annibale, B., et al., Concomitant alterations in intragastric pH and ascorbic acid concentration in patients with Helicobacter pylori gastritis and associated iron deficiency anaemia. Gut, 2003. 52(4): p. 496-501.
120. Sarker, S.A., et al., Helicobacter pylori infection, iron absorption, and gastric acid secretion in Bangladeshi children. American Journal of Clinical Nutrition, 2004. 80(1): p. 149-53.
121. Baysoy, G., et al., Gastric histopathology, iron status and iron deficiency anemia in children with Helicobacter pylori infection.[see comment]. Journal of Pediatric Gastroenterology & Nutrition, 2004. 38(2): p. 146-51.
122. Yip, R., et al., Pervasive occult gastrointestinal bleeding in an Alaska native population with prevalent iron deficiency - role of Helicobacter pylori gastritis. Journal of the American Medical Association, 1997. 277(14): p. 1135-1139.
123. Carnicer, J., R. Badia, and J. Argemi, Helicobacter pylori gastritis and sideropenic refractory anemia.[comment]. Journal of Pediatric Gastroenterology & Nutrition, 1997. 25(4): p. 441.
124. Dufour, C., et al., Helicobacter pylori gastric infection and sideropenic refractory anemia. Journal of Pediatric Gastroenterology & Nutrition, 1993. 17(2): p. 225-227.
125. Konno, M., et al., Iron-deficiency anemia associated with Helicobacter pylori gastritis. Journal of Pediatric Gastroenterology & Nutrition, 2000. 31(1): p. 52-56.
126. Kostaki, M., S. Fessatou, and T. Karpathios, Refractory iron-deficiency anaemia due to silent Helicobacter pylori gastritis in children. European Journal of Pediatrics, 2003. 162(3): p. 177-179.
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127. Annibale, B., et al., Reversal of iron deficiency anemia after Helicobacter pylori eradication in patients with asymptomatic gastritis. Annals of Internal Medicine, 1999. 131(9): p. 668-72.
128. Choe, Y.H., S.K. Kim, and Y.C. Hong, Helicobacter pylori infection with iron deficiency anaemia and subnormal growth at puberty. Archives of Disease in Childhood, 2000. 82(2): p. 136-140.
129. Choe, Y.H., et al., Helicobacter pylori-associated iron-deficiency anemia in adolescent female athletes. The Journal of Pediatrics, 2001. 139(1): p. 100-104.
130. Choe, Y.H., et al., Randomized placebo controlled trail of Helicobacter pylori eradication for iron-deficiency anemai in preadolescent children and adolescents. Helicobacter, 1999. 4: p. 135-139.
131. Choe, Y., J. Lee, and S. Kim, Effect of Helicobacter pylori eradication on sideropenic refractory anaemia in adolescent girls with Helicobacter pylori infection. Acta Paediatrica, 2000. 89(2): p. 154-157.
132. Kurekci, A.E., et al., Is there a relationship between childhood Helicobacter pylori infection and iron deficiency anemia? Journal of Tropical Pediatrics, 2005. 51(3): p. 166-169.
133. Gessner, B.D., et al., A controlled, household‚ randomized, open label trial of the effect that treatment of Helicobacter pylori infection has on iron deficiency in children in rural alaska. The Journal of Infectious Diseases, 2006. 193(4): p. 537-546.
134. Sarker, S.A., et al., Causal relationship of Helicobacter pylori With iron-deficiency anemia or failure of iron supplementation in children. Gastroenterology, 2008. 135(5): p. 1534-1542.
135. Sarker, S.A., et al., High prevalence of cagA and vacA seropositivity in asymptomatic Bangladeshi children with Helicobacter pylori infection. Acta Paediatrica, 2004. 93(11): p. 1432-1436.
136. Halitim, F., et al., High rate of Helicobacter pylori reinfection in children and adolescents. Helicobacter, 2006. 11(3): p. 168-172.
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138. Bickel, G., et al., Guide to Measuring Household Food Security, Revised 2000, United States Department of Agriculture and Food and Nutrition Service, Editors. 2000, USDA: Aexandria, VA.
139. Life Sciences Research Office and S. Anderson, ed., Core indicators of Nutritional State for Difficult to Sample Populations. Journal of Nutrition, 1990. 120: p. 1557S-1600S.
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8 APPENDICES
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Appendix A. Quality control material for dietary questionnaires.
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Qanuippitali? How about us, how are we? CHILD INUIT HEALTH SURVEY– 2007
Nutrition questionnaire response
To be completed by the Dietary coordinator. STUDY NO.
Questionnaire Int. No.: ______ Name: __________________________ Table 1: Check List for the 24-HOUR DIETARY RECALL
Recording of the requested information :
Yes No
1- Time of meal 2- Description in detail of foods eaten 3- Number of servings 4 - Serving models 5- Thickness
Comments: _______________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________ Corrections to do: ___________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________
Completion Date: ____/____/2007 Time: ___/____ m d y h m
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Table 2: Check List for the FOOD FREQUENCY QUESTIONNAIRE Recording of the requested information :
Yes No
Country Food: 1- Column Yes or No 2- When is it consumed In season Off season 3- Frequency # D /W/M /S 4- Number of servings 5- Serving models 6- Thickness Market Food: 1- Column Yes or No 2- Frequency # D /W/M /S 3- Number of servings 4- Serving models 5- Thickness
Comments: _________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________ Corrections to do: ___________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________
Completion Date: ____/____/2007 Time: ___/____
m d y h m
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Appendix B: Clinical protocols and quality control procedures for clinical
equipment
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3. Remove control vials from the refrigerator and allow to warm to room temperature for 15 minutes before mixing.
4. To mix, hold vial horizontally between palms of hands. Do not use mechanical mixer.
a. Roll the vial back and forth for 20-30 seconds, occasionally inverting the vial. Mix vigorously but do not shake.
b. Continue to mix in this manner until the red cells are completely suspended. Vials stored for a long time map require extra mixing.
c. Gently invert the vial 8 – 10 times immediately before sampling. 5. Remove cap from vial. Dispense drop of control on parafilm or other appropriate
material. Recap immediately. 6. Remove cuvette from container and reseal. Fill cuvette by touching tip of cuvette to
blood drop. Wipe outer edges of the cuvette with a Kim Wipe. Do not touch the cuvette opening with the tissue. Take a new sample if you see any air bubbles in the optical eye of the cuvette.
7. Place the cuvette in the holder and slide into the analyzer. Record results in
appropriate column of the Quality Assurance log. 8. Discard cuvette in bio-hazard sharps container. 9. Measure Level 1 (Low), Level 2 (Normal) and Level 3 (High) controls. Place back in
refrigerator after use.
HemoCue® Procedure Only do finger prick if venipuncture is not possible. If using blood from venipuncture, follow Venipuncture Blood Collection protocol and use blood from vacutainer. Invert tube containing whole blood 10 times gently. Pipette 10µL of blood from the capillary tube onto paraffin film. Skip to step 7. 1. Seat the child comfortably. If child is not comfortable, ask caregiver to come to help.
Ensure that the patient's hand is warm so that blood circulates freely before sampling. Rubbing or wrapping it in a warm towel will help warm the hand.
2. The patient’s fingers should be relaxed but not bent to allow for maximum blood flow.
Use only the middle finger or ring finger for sampling; remove rings from the finger before testing.
3. Clean the puncture site with alcohol wipe and dry it completely using a gauze pad. 4. Using a rolling movement of your thumb, lightly press the finger from the top knuckle
towards the tip. This stimulates the flow of blood towards the puncture site. 5. When the thumb has reached the fingertip, maintain gentle pressure and puncture
the side of the fingertip with a sharp, quick motion. Using the side of the finger causes less pain and produces the best flow of blood. Dispose the lancet immediately into a bio-hazard sharps container.
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6. Using a dry gauze pad, wipe away the first two drops of blood to stimulate
spontaneous blood flow. If necessary, gently press the finger until another drop of blood appears. Avoid "milking" the finger. Ensure that the third drop of blood is big enough to fill the cuvette completely in one attempt.
7. Fill the cuvette by touching its pointed tip to the middle of the blood drop - the cuvette
fills automatically by capillary action. This helps avoid trapping air in the cuvette. Never “top off” the cuvette after the first filling. If the cuvette is not filled with the attempt, discard it in the bio-hazard sharps container and use a second cuvette. If you see air bubbles in the optical eye of the cuvette, take a new sample.
8. If a second sample is taken from the same puncture site, it should be collected
before clotting has occurred. Wipe away the remains of the previous blood sample, apply gentle pressure to form another adequate blood drop and collect the sample as described above.
9. Wipe off any excess blood on the sides of the cuvette with a Kim Wipe. Ensure that
no blood is sucked out of the cuvette when wiping it. 10. Place the cuvette in its holder and gently push the holder into the photometer. The
cuvette should be read within 10 minutes after being filled. It takes 15-45 seconds for a reading. Record reading in child’s clinical sheet. Discard the cuvette into a bio-hazard sharps container immediately.
11. Results will be displayed as long as the holder is in the machine unless using
batteries only in which case machine will shut off after 5 minutes. 12. To shut off machine, press the left button until the machine is OFF. Push the holder
into the analyzer.
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Common Problems to Avoid The following are some important points related to the use of the HemoCue® and capillary sampling procedures that should be stressed: 1) Keep the instrument clean, especially the cuvette holder.
A swab dabbed with alcohol can be used to clean away any dirt or dried blood. This should be done at least once a day or when there is a visible build-up of dirt or blood. Be sure the cuvette holder is dry before re-inserting it in the machine.
2) Ensure instrument accuracy
Check the accuracy of the instrument daily, or when performance is questioned, using the control cuvette which comes with each Hemocue® instrument. Keep a daily log of accuracy readings. If the accuracy readings are outside the range of the control cuvette, and the Hemocue® is clean, then the instrument needs to be replaced. Operating temperature for HemoCue® analyzer is 15-30°C. The HemoCue® measures hemoglobin concentrations from 0-256 g/L. Results above 256g/L will be displayed HHH
3) Keep cuvettes clean, dry and away from heat
Cuvettes in unsealed containers are good for 3 months after opening. Keep the container lid closed when not being used to avoid unnecessary exposure of the cuvettes to air, especially in humid conditions. Heat and moisture will denature the chemicals in the cuvette which can lead to inaccurate measurements.
4) Make sure the finger stick is adequate
Wide variations can occur in hemoglobin measurements if the finger stick is inadequate (basically equated to the finger stick not being deep enough to allow adequate flow of blood and a representative concentration of red blood cells). In most cases if the finger stick is done poorly, hemoglobin values will be underestimated and the prevalence of anemia will be overestimated.
5) Avoid poor technique
- Milking the finger (usually related to an inadequate finger stick) to obtain proper blood flow which will underestimate hemoglobin readings.
- Not waiting for at least the 3rd drop of blood to sample. It is recommended
that after wiping away the first two drops of blood using a dry wipe, the third or subsequent drops should be measured. This helps allow for the collection of blood with a representative concentration of red blood cells.
- Mixing alcohol with the blood. The patient’s finger should be totally dried
before the finger prick is performed. Use alcohol to clean the finger before the prick is made and then wipe away each drop of blood with a dry wipe to avoid any mixing of the blood with alcohol. Wiping away the first few drops of blood
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also will minimize the mixing of sweat with blood in hot, humid climates. This error usually underestimates the hemoglobin reading.
Avoid removing a cuvette from its container when your fingers are wet with alcohol. Alcohol coming in contact with the cuvette can denature the needed chemical in the cuvette selected, as well as, other cuvettes still in the container.
- Obstructing blood flow to the puncture site. Do not hold the subject’s hand
so tightly as to obstruct blood flow to the fingers. 6) Adequately fill the cuvette
The cuvette needs to be filled with a drop of blood in one continuous motion. Again this depends on the flow of blood and the size of the drop formed; if it is not adequate, the cuvette will not fill adequately. Do not “top off” the cuvette that is not completely filled. This results in erroneous hemoglobin readings; usually too high.
Any signs of air-bubbles means that the cuvette has not been filled adequately and should be discarded and a new cuvette used. The presence of bubbles will usually underestimate the hemglobin reading.
7) Do not “slam” the cuvette holder into position for reading.
This will avoid spraying blood droplets which can hamper the scanner.
How the HemoCue® works: Sodium deoxycholate haemolyses the erythrocytes and hemoglobin is released. Sodium nitrate converts hemoglobin to methaemoglobin which together with sodium azide, gives azidemethaemoglobin. The absorbance of azidemethaemoglobin is measured at 570nm and 880nm. The absorbance reading is converted to give a measure of total hemoglobin in the sample.
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Summary of common problems and solutions related to capillary sampling and use of the HemoCueTM photometer.
PROBLEM
SOLUTION
Not preparing all needed materials before testing a subject.
Place cuvette, alcohol swab, gauze pad, and lancet on work surface; turn on photometer; pull out the cuvette holder to “locked” position so that digital screen reads “READY”; put on latex gloves.
Selecting a cuvette from its jar with fingers wet with alcohol (the alcohol denatures the chemicals inside the cuvette; thus, the selected cuvette as well others inside the jar can be denatured).
Take cuvette out of its container before handling a wet alcohol swab.
Not drying finger completely after disinfecting with alcohol (since the HemoCue cuvette only hold 10 µL of blood, its volume can be easily affected by even a trace of alcohol on the puncture site).
Firmly wipe the finger using a dry gauze pad. Firm wiping can also help stimulate blood flow to the finger tip.
Inappropriate and shallow finger puncture.
An appropriately deep puncture done with a “quick stab” will result in a better blood flow and more rapid completion of the test. (A number of brands of high quality single-use lancets are now available in the market).
Restricting blood flow to finger tip following the finger-stick.
Release the subject’s finger after the stick to allow blood flow; also hold the subject’s hand without squeezing and restricting blood flow to the finger tip.
Milking the finger (this will lead to mixing of interstitial fluids with the blood drop leading to an inaccurate Hgb reading...usually too low).
A good finger-stick should result in spontaneous blood negating the need to apply pressure to the finger. If stimulating blood flow is needed, apply gentle pressure with the thumb on the opposite side of the finger from the puncture site.
Not appropriately wiping off the first 2 blood drops (this may result in collection of “unrepresentative” blood sample being tested).
Firmly wipe off the first 2 large blood drops. Firm wiping will stimulate blood flow. Discarding the first 2 large drops will allow flow of “representative” blood sample after initial constriction of capillary bed following the finger-stick.
Holding cuvette in inverted position (slit facing down) during filling (this can lead to air bubbles being trapped resulting in erroneous result).
Hold the cuvette with the slit facing up and the pointed tip touching the blood drop.
“Topping off” a partially filled cuvette with repeated blood collection (the reagents in the cuvette are denatured upon contact with the initial amount of blood; red cells of blood introduced later will not be adequately analyzed).
Allow a large blood drop to form on the finger so that it will completely fill the cuvette in one motion. Once filled, hold the cuvette in place for about 2-3 seconds longer to ensure complete filling.
Not cleaning off blood on outside of cuvette before testing (can result in erroneously high Hgb reading).
Wipe off excess blood from sides of cuvette using a “butter knife” motion to ensure that blood from inside the cuvette is not removed.
“Slamming” the cuvette holder into place (can lead to blood drops spattering inside the reading chamber).
Push the cuvette holder gently into position. Once or twice a day clean the cuvette holder with alcohol swab and completely dry before testing. Periodically clean the reading chamber with dry gauze.
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8. Very carefully remove the layer of white blood cells (i.e. the “buffy” coat) from the top of the remaining RBC pellet and discard into biohazard bin.
9. Add enough cold saline to RBC pellet to fill the cryovial (leave sufficient
headspace), mix RBC and saline gently by inverting the tube. It may be necessary to stir the cells very gently. Do flick or shake the tube.
10. Centrifuge again for 15-20 minutes, remove and discard the saline layer and
any remaining buffy coat. Avoid removing RBCs as much as possible but you may need to remove some to completely remove the buffy coat.
11. Add cold BHT solution to the RBC in a 1:1 ratio. (FYI - BHT solution is equal
parts water/methanol + 42 mg/L BHT). Mix by gently inverting tube several times. It may be necessary to stir the cells very gently with the transfer pipette. Do flick or shake the tube.
12. Carefully transfer all the RBC solution to two 1.5 ml cryovials and cap with a
brown cap, place vial in cryovial box, and freeze at -20 immediately.
Sample type
# aliquots Volume Cap Test
Plasma 1 50 µL Red H. pylori
1 500 µL Red Vitamin
D/PTH/SF
1 50 µL Red C-Reactive Protein
2 300 uL Red Remainder 1 Remainder Red Remainder
RBC 2 Brown Fatty acid
13. Store at -20 C until shipped in a cooler with ice packs to Montreal. Upon arrival in the lab, flush tubes with N2 gas and store at -80 C for up to 4 months. (Note: blood volumes of 400 - 500 µl will yield enough RBC for fatty acid analysis as long as high quality solvents are used. Volumes of 75 µl can be used for singlet analyses.)